Image stabilizer

ABSTRACT

An image stabilizer for counteracting image shake of an object image formed on an image pickup device includes an image-pickup-device holding member; a guide device which guides the image-pickup-device holding member so as to be allowed to move linearly in a plane orthogonal to an optical axis; a driving device which moves the image-pickup-device holding member in a guide direction of the guide device to a force receiving portion on the image-pickup-device holding member; and a flexible printed wiring board, extending from the image pickup device, a part of which being fixed to the image-pickup-device holding member at a fixing position thereon. A distance between the fixing position and the force receiving portion is smaller than a distance between the guide device and the force receiving portion in a direction orthogonal to both the optical axis direction and the guide direction.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an image stabilizer which is incorporated in an optical device such as a camera or binoculars.

2. Description of the Related Arts

Optical image stabilizers (shake reduction systems/anti-shake systems) prevent (reduce) image shake of an object image formed at a focal plane by moving a part of an optical system relative to an optical axis thereof so that the part of the optical system shifts from the optical axis in accordance with the direction and the magnitude of vibration (shake) applied to the optical device in which the image stabilizer is incorporated. Such optical image stabilizers can be broadly divided into the following two types: a type of image stabilizer which swings an image-stabilizing optical element about an axis positioned away from the optical axis of the optical system, and another type (X-Y stage type) of image stabilizer which moves an image-stabilizing optical element in a plane orthogonal to the optical axis of the optical system.

The latter type (X-Y stage type) has the advantage that the image stabilizing optical element can be moved precisely in directions to cancel image shake; however, in an apparatus such as an image stabilizer which is required to be driven with great precision, the occurrence of a deleterious moment such as a bending moment or a torsional moment must be considerably suppressed to move the image stabilizing optical element precisely with micrometer accuracy.

Specifically, in the case where an electrical component such as an image pickup device is adopted as the image stabilizing optical element, the load on movements of the image pickup device due to deformation of the flexible printed wiring board which extends from the image pickup device must be prevented from becoming a deleterious moment and must be prevented from causing friction.

SUMMARY OF THE INVENTION

The present invention provides an image stabilizer which includes an image pickup device driven in a plane orthogonal to an optical axis to counteract image shake, wherein the image stabilizer is configured to minimize the occurrence of deleterious moment and friction to thereby make it possible to move the image pickup device with a high degree of precision.

According to an aspect of the present invention, an image stabilizer is provided for counteracting image shake of an object image formed on an image pickup device by moving the image pickup device, the image stabilizer including an image-pickup-device holding member which holds the image pickup device; a guide device which guides the image-pickup-device holding member in a manner to allow the image-pickup-device holding member to move linearly in a plane orthogonal to an optical axis; a driving device which applies a moving force which moves the image-pickup-device holding member in a guide direction of the guide device to a force receiving portion on the image-pickup-device holding member; and a flexible printed wiring board which extends from the image pickup device, a part of the flexible printed wiring board being fixed to the image-pickup-device holding member at a fixing position thereon. A distance between the fixing position and the force receiving portion is smaller than a distance between the guide device and the force receiving portion in a direction orthogonal to both the optical axis direction and the guide direction of the guide device.

It is desirable for the fixing position of the flexible printed wiring board to be positioned between the force receiving portion and the guide device in the direction orthogonal to both the optical axis direction and the guide direction.

It is desirable for the image-pickup-device holding member to include a holding frame to which the image pickup device is fixed; and a flexible printed wiring board support member fixed to the holding frame behind the image pickup device. The flexible printed wiring board is fixed to a part of the flexible printed wiring board support member.

It is desirable for the image stabilizer to include a biasing device which biases the image-pickup-device holding member in one of opposite directions of the guide direction of the guide device; and an intermediate member driven by the driving device to apply the moving force to the force receiving portion against a biasing force of the biasing device.

It is desirable for the intermediate member to be directly in contact with the force receiving portion of the image-pickup-device holding member.

It is desirable for the intermediate member to be coupled to the force receiving portion of the image-pickup-device holding member via a spring.

It is desirable for the intermediate member to include a first moving member which is movable along the guide direction of the guide device by a motor; and a second moving member which is guided along the guide direction and movable relative to the first moving member, wherein the second moving member applies the moving force to the force receiving portion on the image-pickup-device holding member.

The image stabilizer can be incorporated in a digital camera.

In an embodiment, an image stabilizer of a digital camera is provided, including an image-pickup-device holding member which holds an image pickup device on which an object image is formed through a photographing optical system; a guide device which guides the image-pickup-device holding member in a manner to allow the image-pickup-device holding member to move linearly in at least one guide direction in a plane orthogonal to an optical axis of the photographing optical system; a driving device which applies a moving force to a force receiving portion on the image-pickup-device holding member to move the image-pickup-device holding member in the guide direction of the guide device; and a flexible printed wiring board which extends from the image pickup device in an internal space of a camera body, a part of the flexible printed wiring board being fixed to the image-pickup-device holding member at a fixing position thereon. A distance between the fixing position and the force receiving portion is smaller than a distance between the guide device and the force receiving portion in a direction orthogonal to both the optical axis direction and the guide direction of the guide device.

According to the present invention, a high-reliability image stabilizer is achieved, which includes an image pickup device driven in a plane orthogonal to an optical axis to counteract image shake, wherein the image stabilizer minimizes the occurrence of deleterious moment and friction to thereby make it possible to move the image pickup device with a high degree of precision, is achieved.

The present disclosure relates to subject matter contained in Japanese Patent Application No. 2006-27439 (filed on Feb. 3, 2006) which is expressly incorporated herein by reference in its entirety.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be described below in detail with reference to the accompanying drawings in which:

FIG. 1 is a front elevational view of an embodiment of a digital camera equipped with an image stabilizer according to the present invention;

FIG. 2 is a longitudinal sectional view of the digital camera shown in FIG. 1 in a ready-to-photograph state of the zoom lens thereof;

FIG. 3 is a longitudinal sectional view of the digital camera shown in FIG. 1 in the fully-retracted state of the zoom lens;

FIG. 4 is a perspective view of the zoom lens of the digital camera shown in FIG. 1 in the fully-retracted state of the zoom lens;

FIG. 5 is an exploded perspective view of a portion of the zoom lens shown in FIG. 4;

FIG. 6 is an exploded perspective view of another portion of the zoom lens shown in FIG. 4;

FIG. 7 is a front perspective view of an image stabilizing unit (image stabilizing mechanism) shown in FIG. 5;

FIG. 8 is a rear perspective view of the image stabilizing unit shown in FIG. 5 from which a movable plate and a stationary cover are removed;

FIG. 9 is a rear perspective view of the image stabilizing unit shown in FIG. 5, viewed from an angle different from the angle of FIG. 8;

FIG. 10 is an exploded perspective view of the image stabilizing unit;

FIG. 11 is an exploded perspective view of a portion of the image stabilizing unit in the vicinity of a stationary holder thereof;

FIG. 12 is an exploded front perspective view of an X-axis direction moving stage, a CCD image sensor, a CCD retaining plate and associated elements shown in FIG. 10;

FIG. 13 is a rear perspective view of the X-axis direction moving stage shown in FIG. 12 from which the flexible printed wiring board and the movable plate that are shown in FIG. 10 are removed;

FIG. 14 is a front perspective view of a first X-axis direction moving member, a second X-axis direction moving member and an associated extension joining spring of the image stabilizing unit, showing an exploded state thereof;

FIG. 15 is a rear perspective view of the first X-axis direction moving member, the second X-axis direction moving member and the associated extension joining spring that are shown in FIG. 14, showing an exploded state and an assembled state thereof;

FIG. 16 is an exploded perspective view of a Y-axis direction moving member, a Y-axis direction moving stage and an associated extension joining spring of the image stabilizing unit;

FIG. 17 is a rear perspective view of the Y-axis direction moving member, the Y-axis direction moving stage and the associated extension joining spring that are shown in FIG. 16, showing an exploded state and an assembled state thereof;

FIG. 18 is a front perspective view of the image stabilizing unit from which the stationary holder is removed;

FIG. 19 is a rear perspective view of the elements of the image stabilizing unit shown in FIG. 18;

FIG. 20 is a front perspective view of the elements of the image stabilizing unit shown in FIGS. 18 and 19 from which drive motors, photo-interrupters and biasing springs are further removed;

FIG. 21 is a rear perspective view of the elements of the image stabilizing unit shown in FIG. 20;

FIG. 22 is a front perspective view of the elements of the image stabilizing unit shown in FIGS. 20 and 21 from which the second X-axis direction moving member and the Y-axis direction moving member are further removed;

FIG. 23 is a rear perspective view of the elements of the image stabilizing unit shown in FIG. 22;

FIG. 24 is a diagrammatic illustration of the image stabilizing unit, showing the structure thereof;

FIG. 25 is a block diagram illustrating a configuration of electrical circuits of the digital camera shown in FIGS. 1 through 3;

FIG. 26 is a view similar to that of FIG. 18, showing another embodiment (second embodiment) of the image stabilizing unit from which the stationary holder is removed;

FIG. 27 is a rear perspective view of the elements of the image stabilizing unit shown in FIG. 26;

FIG. 28 is a diagrammatic illustration of the second embodiment of the image stabilizing unit, showing the structure thereof;

FIG. 29 is an exploded front perspective view of a CCD unit and a stationary cover shown in FIG. 10;

FIG. 30 is an exploded rear perspective view of the CCD unit;

FIG. 31 is an exploded rear perspective view of the CCD unit, showing a state where the CCD retaining plate is fixed to the X-axis direction moving stage;

FIG. 32 is a rear perspective view of the CCD unit in an assembled state thereof;

FIG. 33 is a cross sectional view of the image stabilizing unit in a state before an inclination angle adjustment is made to the CCD image sensor;

FIG. 34 is a cross sectional view of the image stabilizing unit in a state after the inclination angle adjustment has been made to the CCD image sensor;

FIG. 35 is an enlarged cross sectional view of a portion of the image stabilizing unit in the vicinity of one of the two adjusting screws shown in FIG. 33;

FIG. 36 is an enlarged cross sectional view of a portion of the image stabilizing unit in the vicinity of one of the two adjusting screws shown in FIG. 34;

FIG. 37 is a cross sectional view of the image stabilizing unit, taken along a plane in which two compression coil springs of the CCD unit are positioned;

FIG. 38 is a rear perspective view of the image stabilizing unit in a state where the movable plate and the stationary cover are installed;

FIG. 39 is a rear perspective view of the image stabilizing unit with the stationary cover partly cut away for clarity;

FIG. 40 is a longitudinal sectional view of a portion of the image stabilizing unit, showing the arrangement of the flexible printed wiring board that extends from the CCD image sensor;

FIG. 41 is a view similar to that of FIG. 24, wherein the flexible printed wiring board that extends from the CCD image sensor is shown by a two-dot chain line;

FIG. 42 is a view similar to that of FIG. 41, showing a comparative example wherein the flexible printed wiring board extends from the CCD image sensor in the direction opposite to the direction of the flexible printed wiring board shown in FIG. 41;

FIG. 43 is a diagrammatic illustration of another embodiment (third embodiment) of the image stabilizing unit, wherein the relative position between the guide mechanism for the X-axis direction moving stage and a force receiving portion is different from those in the case of the image stabilizing unit shown in FIG. 41;

FIG. 44 is a diagrammatic illustration of another embodiment (fourth embodiment) of the image stabilizing unit, wherein the flexible printed wiring board extends from the CCD image sensor in a direction different from the direction of the flexible printed wiring board shown in FIG. 41; and

FIG. 45 is a view similar to that of FIG. 44, showing a comparative example wherein the flexible printed wiring board extends from the CCD image sensor in the direction opposite to the direction of the flexible printed wiring board shown in FIG. 44.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 shows an outward appearance of a digital camera 200 which incorporates an image stabilizer according to the present invention. The digital camera 200 is provided on the front of a camera body 202 thereof with a zoom lens (zoom lens barrel) 201, an optical viewfinder 203 and a flash 204, and is provided on the top of the camera body 202 with a shutter button 205.

The zoom lens 201 of the digital camera 200, longitudinal sectional views of which are shown in FIGS. 2 and 3, is driven to advance toward the object side (leftward as viewed in FIGS. 2 and 3) from the camera body 202 as shown in FIG. 2 during a photographing operation. When photography is not carried out, the digital camera 200 moves from a ready-to-photograph state shown in FIG. 2 to a fully-retracted state shown in FIG. 3 in which the zoom lens 201 is accommodated (fully retracted) in the camera body 202 as shown in FIG. 3. In FIG. 2, the upper half and the lower half of the zoom lens 201 from a photographing optical axis Z1 show the ready-to-photograph state of the zoom lens 201 at the wide-angle extremity and the telephoto extremity, respectively. As shown in FIGS. 5 and 6, the zoom lens 201 is provided with a plurality of ring members (hollow-cylindrical members): a second linear guide ring 10, a cam ring 11, a third movable barrel 12, a second movable barrel 13, a first linear guide ring 14, a first movable barrel 15, a helicoid ring 18 and a stationary barrel 22 which are substantially concentrically arranged about a common axis that is shown as a lens barrel axis Z0 in FIGS. 2 and 3.

The zoom lens 201 is provided with a photographing optical system including a first lens group LG1, a shutter S, an adjustable diaphragm A, a second lens group LG2, a third lens group LG3, a low-pass filter 25 and a CCD image sensor 60 that serves an image pickup device. Optical elements from the first lens group LG1 to the CCD image sensor 60 are positioned on the photographing optical axis (common optical axis) Z1 when the zoom lens 201 is in a ready-to-photograph state. The photographing optical axis Z1 is parallel to the lens barrel axis Z0 and positioned below the lens barrel axis Z0. The first lens group LG1 and the second lens group LG2 are moved along the photographing optical axis Z1 in a predetermined moving manner to perform a zooming operation, and the third lens group LG3 is moved along the photographing optical axis Z1 to perform a focusing operation. In the following description, the term “optical axis direction” refers to a direction parallel to the photographing optical axis Z1 and the terms “object side” and “image side” refer to forward and rearward of the digital camera 200, respectively. Additionally, in the following description, the vertical direction and the horizontal direction of the digital camera 200 in a plane orthogonal to the photographing optical axis Z1 are defined as a Y-axis direction and an X-axis direction, respectively.

The stationary barrel 22 is positioned in the camera body 202 and fixed thereto, and a stationary holder 23 is fixed to a rear portion of the stationary barrel 22. The CCD image sensor 60 and the low-pass filter 25 are supported by the stationary holder 23 via a Y-axis direction moving stage 71 and an X-axis direction moving stage (image-pickup-device holding member/holding frame) 21 to be movable in the X-axis direction and the Y-axis direction. The digital camera 200 is provided behind the stationary holder 23 with an LCD panel 20 which indicates visual images and various photographic information. The LCD panel 20 is installed so that the viewing area thereof faces toward the back side of the camera body 202, and a flexible printed wiring board 20 a extends from the bottom end of the LCD panel 20.

The zoom lens 201 is provided in the stationary barrel 22 with a third lens frame 51 which supports and holds the third lens group LG3. The zoom lens 201 is provided between the stationary holder 23 and the stationary barrel 22 with a pair of guide shafts 52 and 53 which extend parallel to the photographing optical axis Z1 to guide the third lens frame 51 in the optical axis direction without rotating the third lens frame 51 about the lens barrel axis Z0. The third lens frame 51 is biased forward by a third lens frame biasing spring (extension coil spring) 55. The digital camera 200 is provided with a focusing motor 160 having a rotary drive shaft which is threaded to serve as a feed screw, and the rotary drive shaft is screwed through a screw hole formed on an AF nut 54. If the AF nut 54 is moved rearward by a rotation of the rotary drive shaft of the focusing motor 160, the third lens frame 51 is pressed by the AF nut 54 to move rearward. Conversely, if the AF nut 54 is moved forward, the third lens frame 51 follows the AF nut 54 to move forward by the biasing force of the third lens frame biasing spring 55. Due to this structure, the third lens frame 51 can be moved forward and rearward in the optical axis direction.

As shown in FIG. 4, the digital camera 200 is provided on the stationary barrel 22 with a zoom motor 150 which is supported by the stationary barrel 22. The driving force of the zoom motor 150 is transferred to a zoom gear 28 (see FIG. 5) via a reduction gear train (not shown). The zoom gear 28 is rotatably fitted on a zoom gear shaft 29 extending parallel to the photographing optical axis Z1. Front and rear ends of the zoom gear shaft 29 are fixed to the stationary barrel 22 and the stationary holder 23, respectively.

The helicoid ring 18 is positioned inside the stationary barrel 22 and supported thereby. The helicoid ring 18 is rotated by rotation of the zoom gear 28. The helicoid ring 18 is moved forward and rearward in the optical axis direction while being rotated about the lens barrel axis Z0 via a helicoid structure (provided between the helicoid ring 18 and the stationary barrel 22) within a predetermined range in the optical axis direction between the position in the fully-retracted state of the zoom lens 201 shown in FIG. 3 to the position in the state of the zoom lens 201 immediately before the zoom lens 201 is in the ready-to-photograph state thereof at the wide-angle extremity shown by the upper half of the zoom lens 201 in FIG. 2. In a ready-to-photograph state of the zoom lens 201 shown in FIG. 2 (between the wide-angle extremity and the telephoto extremity), the helicoid ring 18 is rotated at a fixed position without moving in the optical axis direction. The first movable barrel 15 is coupled to the helicoid ring 18 to be rotatable together with the helicoid ring 18 about the lens barrel axis Z0 and to be movable together with the helicoid ring 18 in the optical axis direction.

The first linear guide ring 14 is positioned inside the first movable barrel 15 and the helicoid ring 18 and supported thereby. The first linear guide ring 14 is guided linearly in the optical axis direction via linear guide grooves formed on the stationary barrel 22, and is engaged with the first movable barrel 15 and the helicoid ring 18 to be rotatable about the lens barrel axis Z0 relative to the first movable barrel 15 and the helicoid ring 18, and to be movable in the optical axis direction together with the first movable barrel 15 and the helicoid ring 18.

As shown in FIG. 5, the first linear guide ring 14 is provided with a set of three through-slots 14 a (only two of which appear in FIG. 5) which radially penetrate the first linear guide ring 14. Each through-slot 14 a includes a circumferential slot portion and an inclined lead slot portion which extends obliquely rearward from one end of the circumferential slot portion. The inclined lead slot portion is inclined with respect to the optical axis direction, while the circumferential slot portion extends circumferentially about the lens barrel axis Z0. A set of three followers 11 a (only two of which appear in FIG. 6) which project radially outward from an outer peripheral surface of the cam ring 11 are engaged in the set of three through-slots 14 a, respectively. The set of three followers 11 a are further engaged in a set of three rotation transfer grooves 15 a which are formed on an inner peripheral surface of the first movable barrel 15 and extend parallel to the photographing optical axis Z1 so that the cam ring 11 rotates with the first movable barrel 15. When the set of three followers 11 a are engaged in the lead slot portions of the set of three through-slots 14 a, respectively, the cam ring 11 is moved forward and rearward in the optical axis direction while being rotated about the lens barrel axis Z0 and guided by the set of three through-slots 14 a. On the other hand, when the set of three followers 11 a are engaged in the circumferential slot portions of the set of three through-slots 14 a, respectively, the cam ring 11 is rotated at a fixed position without moving in the optical axis direction. Similar to the helicoid ring 18, the cam ring 11 is moved forward and rearward in the optical axis direction while being rotated about the lens barrel axis Z0 within a predetermined range in the optical axis direction between the position in the fully-retracted state of the zoom lens 201 shown in FIG. 3 to the position in the state of the zoom lens 201 immediately before the zoom lens 201 enters the ready-to-photograph state thereof at the wide-angle extremity (shown by the upper half of the zoom lens 201 in FIG. 2), and the cam ring 11 is rotated at a fixed position without moving in the optical axis direction in a ready-to-photograph state of the zoom lens 201 shown in FIG. 2 (between the wide-angle extremity and the telephoto extremity).

The first linear guide ring 14 guides the second linear guide ring 10 and the second movable ring 13 linearly in the optical axis direction by linear guide grooves which are formed on an inner peripheral surface of the first linear guide ring 14 to extend parallel to the photographing optical axis Z1. The second linear guide ring 10 guides a second lens group moving frame 8, which indirectly supports the second lens group LG2, linearly in the optical axis direction, while the second movable barrel 13 guides the third movable barrel 12, which indirectly supports the first lens group LG1, linearly in the optical axis direction. Each of the second linear guide ring 10 and the second movable barrel 13 is supported by the cam ring 11 to be rotatable relative to the cam ring 11 about the lens barrel axis Z0 and to be movable together with the cam ring 11 in the optical axis direction.

The cam ring 11 is provided on an inner peripheral surface thereof with a plurality of inner cam grooves 11 b for moving the second lens group LG2, and the second lens group moving frame 8 is provided on an outer peripheral surface thereof with a plurality of cam followers 8 a which are engaged in the plurality of inner cam grooves 11 b, respectively. Since the second lens group moving frame 8 is guided linearly in the optical axis direction without rotating via the second linear guide ring 10, a rotation of the cam ring 11 causes the second lens group moving frame 8 to move in the optical axis direction in a predetermined moving manner in accordance with contours of the plurality of inner cam grooves 11 b.

As shown in FIG. 6, the zoom lens 201 is provided inside the second lens group moving frame 8 with a second lens frame 6 which supports and holds the second lens group LG2. The second lens frame 6 is supported by the second lens group moving frame 8 to be rotatable (swingable) about a pivot shaft 33. The pivot shaft 33 extends parallel to the photographing optical axis Z1. The second lens frame 6 is swingable about the pivot shaft 33 between a photographing position (shown in FIG. 2) where the second lens group LG2 is positioned on the photographing optical axis Z1, and a radially retracted position (shown in FIG. 3) where the optical axis of the second lens group LG2 is retracted away from the photographing optical axis Z1 to be positioned above the photographing optical axis Z1. The second lens frame 6 is biased to rotate in a direction toward the aforementioned photographing position of the second lens frame 6 by a torsion spring 39. The stationary holder 23 is provided with a position-control cam bar 23 a (see FIG. 5) which projects forward from the stationary holder 23 to be engageable with the second lens frame 6 so that the position-control cam bar 23 a comes into pressing contact with the second lens frame 6 to rotate the second lens frame 6 to the radially retracted position thereof against the biasing force of the torsion spring 39 when the second lens group moving frame 8 moves rearward in a retracting direction to approach the stationary holder 23.

The second movable barrel 13, which is guided linearly in the optical axis direction without rotating by the second linear guide ring 10, guides the third movable barrel 12 linearly in the optical axis direction. The third movable barrel 12 is provided on an inner peripheral surface thereof with a set of three cam followers 31 (see FIG. 6) which project radially inwards, and the cam ring 11 is provided on an outer peripheral surface thereof with a set of three outer cam grooves 11 c (cam grooves for moving the first lens group LG1; only two of them appear in FIG. 6) in which the set of three cam followers 31 are slidably engaged, respectively. The zoom lens 201 is provided inside the third movable barrel 12 with a first lens frame 1 which is supported by the third movable barrel 12 via a first lens group adjustment ring 2.

The zoom lens 201 is provided between the first and second lens groups LG1 and LG2 with a shutter unit 100 including the shutter S and the adjustable diaphragm A. The shutter unit 100 is positioned inside the second lens group moving frame 8 and fixed thereto.

Operations of the zoom lens 201 that has the above described structure will be discussed hereinafter. In the state shown in FIG. 3, in which the zoom lens 201 is in the fully-retracted state, the zoom lens 201 is fully accommodated in the camera body 202. Upon a main switch 101 (see FIG. 25) provided on an outer surface of the camera body 202 being turned ON in the fully-retracted state of the zoom lens 201 shown in FIG. 3, the zoom motor 150 is driven to rotate in a lens barrel advancing direction by control of a control circuit 102 (see FIG. 25) provided in the camera body 202. This rotation of the zoom motor 150 rotates the zoom gear 28. The rotation of the zoom gear 28 causes a combination of the first movable barrel 15 and the helicoid ring 18 to move forward while rotating about the lens barrel axis Z0 due to the aforementioned helicoid structure, and further causes the first linear guide ring 14 to move forward linearly together with the first movable barrel 15 and the helicoid ring 18. At this time, the cam ring 11 which rotates by rotation of the first movable barrel 15 moves forward in the optical axis direction by an amount of movement corresponding to the sum of the amount of the forward movement of the first linear guide ring 14 and the amount of the forward movement of the cam ring 11 by a leading structure between the first linear guide ring 14 and the cam ring 11, i.e., by the engagement of the inclined lead slot portions of the set of three through-slots 14 a and the set of three followers 11 a of the cam ring 11, respectively. Once the helicoid ring 18 and the cam ring 11 advance to respective predetermined points thereof, the functions of a rotating/advancing mechanism (the aforementioned helicoid structure) between the helicoid ring 18 and the stationary barrel 22 and another rotating/advancing mechanism (the aforementioned leading structure) between the cam ring 11 and the first linear guide ring 14 are canceled, so that each of the helicoid ring 18 and the cam ring 11 rotates about the lens barrel axis Z0 without moving in the optical axis direction.

A rotation of the cam ring 11 causes the second lens group moving frame 8, which is positioned inside the cam ring 11 and guided linearly in the optical axis direction via the second linear guide ring 10, to move in the optical axis direction with respect to the cam ring 11 in a predetermined moving manner due to the engagement of the set of three cam followers 8 a with the set of three inner cam grooves 11 b, respectively. In the state shown in FIG. 3, in which the zoom lens 201 is in the fully-retracted state, the second lens frame 6, which is positioned inside the second lens group moving frame 8, is held in the radially retracted position off the photographing optical axis Z1 by the action of the position-control cam bar 23 a, which projects forward from the stationary holder 23. During the course of movement of the second lens group moving frame 8 from the retracted position to a position in the zooming range, the second lens frame 6 is disengaged from the position-control cam bar 23 a to rotate about the pivot shaft 33 from the radially retracted position to the photographing position shown in FIG. 2, where the optical axis of the second lens group LG2 coincides with the photographing optical axis Z1, by the spring force of the torsion spring 39. Thereafter, the second lens frame 6 remains held in the photographing position until the zoom lens 201 is retracted into the camera body 201.

In addition, a rotation of the cam ring 11 causes the third movable barrel 12, which is positioned around the cam ring 11 and guided linearly in the optical axis direction via the second movable barrel 13, to move in the optical axis direction relative to the cam ring 11 in a predetermined moving manner due to the engagement of the set of three cam followers 31 with the set of three outer cam grooves 11 c of the cam ring 11, respectively.

Accordingly, an axial position of the first lens group LG1 relative to an imaging plane (imaging surface/light receiving surface of the CCD image sensor 60) when the first lens group LG1 is moved forward from the fully-retracted position is determined by the sum of the amount of forward movement of the cam ring 11 relative to the stationary barrel 22 and the amount of movement of the third external barrel 12 relative to the cam ring 11, while an axial position of the second lens group LG2 relative to the imaging plane when the second lens group LG2 is moved forward from the fully-retracted position is determined by the sum of the amount of forward movement of the cam ring 11 relative to the stationary barrel 22 and the amount of movement of the second lens group moving frame 8 relative to the cam ring 11. A zooming operation is carried out by moving the first and second lens groups LG1 and LG2 on the photographing optical axis Z1 while changing the air-distance therebetween. When the zoom lens 201 is driven to advance from the fully-retracted position shown in FIG. 3, the zoom lens 201 firstly moves to a position shown above the photographing lens axis Z1 in FIG. 2 in which the zoom lens 201 is at the wide-angle extremity. Subsequently, the zoom lens 201 moves a position state shown below the photographing lens axis Z1 in FIG. 2 in which the zoom lens 201 is at the telephoto extremity by a further rotation of the zoom motor 150 in a lens barrel advancing direction thereof. As can be seen from FIG. 2, the air-distance between the first and second lens groups LG1 and LG2 when the zoom lens 201 is at the wide-angle extremity is greater than when the zoom lens 201 is at the telephoto extremity. When the zoom lens 201 is at the telephoto extremity as shown below the photographing lens axis Z1 in FIG. 2, the first and second lens groups LG1 and LG2 have moved to approach each other to have an air-distance therebetween which is smaller than the air-distance in the zoom lens 201 at the wide-angle extremity. This variation of the air-distance between the first and second lens groups LG1 and LG2 for the zooming operation is achieved by contours of the plurality of inner cam grooves 11 b (for moving the second lens group LG2) and the set of three outer cam grooves 11 c (for moving the first lens group LG1) of the cam ring 11. In the zooming range between the wide-angle extremity and the telephoto extremity, the cam ring 11, the first movable barrel 15 and the helicoid ring 18 rotate at their respective axial fixed positions, i.e., without moving in the optical axis direction.

In a ready-to-photograph state of the zoom lens 201 between the wide-angle extremity and the telephoto extremity, a focusing operation is carried out by moving the third lens group LG3 (the third lens frame 51) along the photographing optical axis Z1 by driving the AF motor 160 in accordance with object distance information obtained by a distance measuring device of the digital camera 200.

Upon the main switch 101 being turned OFF, the zoom motor 150 is driven to rotate in a lens barrel retracting direction so that the zoom lens 201 operates in the reverse manner to the above described advancing operation to fully retract the zoom lens 201 into the camera body 202 as shown in FIG. 3. During the course of this retracting movement of the zoom lens 201, the second lens frame 6 rotates about the pivot shaft 33 to the radially retracted position by the position-control cam bar 23 a while moving rearward together with the second lens group moving frame 8. When the zoom lens 201 is fully retracted into the camera body 202, the second lens group LG2 is retracted into the space radially outside the space in which the third lens group LG3, the low-pass filter LG4 and the CCD image sensor 60 are retracted as shown in FIG. 3, i.e., the second lens group LG2 is radially retracted into an axial range substantially identical to an axial range in the optical axis direction in which the third lens group LG3, the low-pass filter LG4 and the CCD image sensor 60 are positioned. This structure of the digital camera 200 for retracting the second lens group LG2 in this manner reduces the length of the zoom lens 201 when the zoom lens 201 is fully retracted, thus making it possible to reduce the thickness of the camera body 202 in the optical axis direction, i.e., in the horizontal direction as viewed in FIG. 3.

The digital camera 200 is provided with an image stabilizer (optical image stabilizer). This image stabilizer moves the CCD image sensor 60 in a plane orthogonal to the photographing optical axis Z1 to counteract image shake of an object image captured by the CCD image sensor 60 in accordance with the direction and the magnitude of vibration (hand shake) applied to the digital camera 200. This control is performed by the control circuit 102 (FIG. 25). FIGS. 7 through 9 show an image stabilizing unit IS including the CCD image sensor 60. FIG. 10 is an exploded perspective view of the entire image stabilizing unit IS and FIGS. 11 through 23 are perspective views or exploded perspective views of various portions of the image stabilizing unit IS.

The stationary holder 23 is provided with a Y-axis direction guide rod 73 which extends in the Y-axis direction (the vertical direction of the digital camera 200). The Y-axis direction moving stage 71 is provided with a guide hole 71 a (see FIG. 16) in which the Y-axis direction guide rod 73 is engaged so that the Y-axis direction moving stage 71 is supported by the Y-axis direction guide rod 73 to be freely slidable thereon. The stationary holder 23 is provided with a rotation prevention rod 79 substantially parallel to the Y-axis direction guide rod 73. The Y-axis direction moving stage 71 is provided, on the laterally opposite sides thereof from the guide hole 71 a, with a guide groove 71 b (see FIG. 16) in which the rotation prevention rod 79 is engaged. When moved on the Y-axis direction guide rod 73 therealong, the Y-axis direction moving stage 71 is prevented from tilting relative to the photographing optical axis Z1 by the engagement of the rotation prevention rod 79 with the guide groove 71 b. The Y-axis direction moving stage 71 is provided thereon with an X-axis direction guide rod 72 which extends in the X-axis direction (the horizontal direction of the digital camera 200) and is perpendicular to the Y-axis direction guide rod 73. The X-axis direction stage 21 is provided with a guide hole 21 a (see FIGS. 12 and 13) in which the X-axis direction guide rod 72 is engaged so that the X-axis direction moving stage 21 is freely slidable thereon in the X-axis direction. The Y-axis direction moving stage 71 is provided with a rotation prevention rod 74 substantially parallel to the X-axis direction guide rod 72. The X-axis direction moving stage 21 is provided at the bottom thereof with a guide groove 21 b in which the rotation prevention rod 74 is engaged. When moved on the X-axis direction guide rod 72 therealong, the X-axis direction moving stage 21 is prevented from tilting relative to the photographing optical axis Z1 by the engagement of the rotation prevention rod 74 with the guide groove 21 b. Accordingly, the CCD image sensor 60 is supported by the stationary holder 23 via the Y-axis direction moving stage 71 and the X-axis direction moving stage 21 to be movable in two axial directions orthogonal to each other in a plane orthogonal to the photographing optical axis Z1. The range of movement of the X-axis direction stage 21 is defined by inner peripheral surfaces of the Y-axis direction moving stage 71, while the range of movement of the Y-axis direction moving stage 71 is defined by inner peripheral surfaces of the stationary holder 23.

The image stabilizing unit IS is provided with an X-axis direction stage biasing spring (biasing device) 87 x which is extended and installed between a spring hook 21 v formed on the X-axis direction moving stage 21 and a spring hook 23 vx formed on the stationary holder 23. The X-axis direction stage biasing spring 87 x is an extension coil spring and biases the X-axis direction moving stage 21 rightward as viewed from the front of the zoom lens 201 (leftward as viewed from the rear of the zoom lens 201). The image stabilizing unit IS is provided with a Y-axis direction stage biasing spring (biasing device) 87 y which is extended and installed between a spring hook 71 v formed on the Y-axis direction moving stage 71 and a spring hook 23 vy formed on the stationary holder 23. The Y-axis direction stage biasing spring 87 y is an extension coil spring and biases the Y-axis direction moving stage 71 downward.

As shown in FIGS. 16 and 17, the image stabilizing unit IS is provided on one side of the Y-axis direction moving stage 71 with a Y-axis direction moving member 80 which is supported by the Y-axis direction moving stage 71. The Y-axis direction moving member 80 is elongated in the Y-axis direction and provided in the vicinity of upper and lower ends of the Y-axis direction moving member 80 with a movement limit lug 80 a and a movement limit lug 80 b, respectively. The Y-axis direction moving member 80 is provided at a lower end thereof with a guide pin 80 c which extends downward from the movement limit lug 80 a. The movement limit lug 80 b is provided with a pair of guide holes 80 d. The Y-axis direction moving member 80 is further provided in the vicinity of the pair of guide holes 80 d with a nut contacting portion 80 e and a linear groove 80 f (see FIG. 16), and is further provided, on a vertically straight portion of the Y-axis direction moving member 80 between the movement limit lug 80 a and the movement limit lug 80 b, with a spring hook 80 g (see FIG. 17). The linear groove 80 f is elongated in the Y-axis direction.

The Y-axis direction moving stage 71 is provided with a movement limit lug 71 c and a movement limit lug 71 d which face the movement limit lug 80 a and the movement limit lug 80 b of the Y-axis direction moving member 80, respectively. The movement limit lug 71 c is provided with a guide hole 71 e in which the guide pin 80 c is slidably engaged, while the movement limit lug 71 d is provided with a pair of guide pins 71 f which extend upward to be slidably engaged in the pair of guide holes 80 d, respectively. The Y-axis direction moving stage 71 is provided on a vertically straight portion thereof between the movement limit lug 71 c and a movement limit lug 71 d, with a spring hook 71 g.

The Y-axis direction moving stage 71 and the Y-axis direction moving member 80 are guided to be movable relative to each other in the Y-axis direction by the engagement of the guide hole 71 e with the guide pin 80 c and the engagement of the pair of guide pins 71 f with the pair of guide holes 80 d. The image stabilizing unit IS is provided with an extension joining spring 81 y which is extended and installed between the spring hook 71 g of the Y-axis direction moving stage 71 and the spring hook 80 g of the Y-axis direction moving member 80. The extension joining spring 81 y biases the Y-axis direction moving stage 71 and the Y-axis direction moving member 80 in opposite directions to bring the movement limit lug 80 a and the movement limit lug 71 c into contact with each other and to bring the movement limit lug 80 b and the movement limit lug 71 d into contact with each other, i.e., in opposite directions to move the Y-axis direction moving stage 71 and the Y-axis direction moving member 80 upward and downward, respectively.

An X-axis direction guide rod 77 and a rotation prevention rod 78, which are different from the X-axis direction guide rod 72 and the rotation prevention rod 74, respectively, are fixed to the stationary holder 23 to extend in the X-axis direction. As shown in FIGS. 14 and 15, the image stabilizing unit IS is provided with a first X-axis direction moving member 75 which is elongated in the X-axis direction. The first X-axis direction moving member 75 is provided, in the vicinity of opposite ends of the first X-axis direction moving member 75 in the X-axis direction, with a movement limit lug 75 a and a movement limit lug 75 b, respectively. A pair of guide holes 75 c (see FIG. 15) in which the X-axis direction guide rod 77 is inserted are formed on the movement limit lugs 75 a and 75 b, respectively, to be aligned in the X-axis direction. A guide hole 75 d in which the rotation prevention rod 78 is inserted is formed on the movement limit lug 75 a. No guide hole corresponding to the guide hole 75 d is formed on the movement limit lug 75 b. The first X-axis direction moving member 75 is supported by the X-axis direction guide rod 77 to be freely slidable thereon in the X-axis direction, and is prevented from rotating about the X-axis direction guide rod 77 (from tilting relative to the photographing optical axis Z1) by the engagement of the rotation prevention rod 78 with the guide hole 75 d. The movement limit lug 75 a is provided between the associated guide hole 75 c and the guide hole 75 d with a pair of guide holes 75 e. The movement limit lug 75 b is provided, above the associated guide hole 75 c in the Y-axis direction (see FIG. 15), with a guide pin 75 f which extends in the X-axis direction in a direction away from the movement limit lug 75 a. The first X-axis direction moving member 75 is further provided at the bottom of the movement limit lug 75 a with a linkage projection 75 g, and is further provided, on a horizontally straight portion of the first X-axis direction moving member 75 between the movement limit lug 75 a and a movement limit lug 75 b, with a spring hook 75 h.

The image stabilizing unit IS is provided on the first X-axis direction moving member 75 with a second X-axis direction moving member 76. The second X-axis direction moving member 76 is provided with a movement limit lug 76 a and a movement limit lug 76 b which are separate from each other in the X-axis direction. The movement limit lug 76 a is provided with a pair of guide pins 76 c which extend in the X-axis direction to be slidably engaged in the pair of guide holes 75 e of the first X-axis direction moving member 75, respectively, and the movement limit lug 76 b is provided with a guide hole 76 d in which the guide pin 75 f of the first X-axis direction moving member 75 is slidably engaged. The second X-axis direction moving member 76 is further provided in the vicinity of the movement limit lug 76 a with a nut contacting portion 76 e and a linear groove 76 f (see FIG. 15), and is further provided, on a horizontally straight portion of the second X-axis direction moving member 76 between the movement limit lug 76 a and the movement limit lug 76 b, with a spring hook 76 g. The linear groove 76 f is elongated in the X-axis direction.

The first X-axis direction moving member 75 and the second X-axis direction moving member 76 are guided to be movable relative to each other in the X-axis direction by the engagement of the pair of guide holes 75 e with the pair of guide pins 76 c and the engagement of the guide pin 75 f with the guide hole 76 d. The image stabilizing unit IS is provided with an extension joining spring 81 x which is extended and installed between the spring hook 75 h of the first X-axis direction moving member 75 and the spring hook 76 g of the second X-axis direction moving member 76. The extension joining spring 81 x biases the first X-axis direction moving member 75 and the second X-axis direction moving member 76 in opposite directions to bring the movement limit lug 75 a and the movement limit lug 76 a into contact with each other and to bring the movement limit lug 75 b and the movement limit lug 76 b into contact with each other.

The linkage projection 75 g of the first X-axis direction moving member 75 is in contact with a transfer roller (receiving portion) 21 c (see FIGS. 12 and 13) mounted to the X-axis direction stage 21 so that a moving force in the X-axis direction is transferred from the first X-axis direction moving member 75 to the X-axis direction stage 21 via the contacting engagement between the linkage projection 75 g and the transfer roller 21 c. The transfer roller 21 c is supported by a rotation pin parallel to the photographing optical axis Z1 so as to be freely rotatable on the rotation pin. When the X-axis direction stage 21 moves with the Y-axis direction moving stage 71 in the Y-axis direction, the transfer roller 21 c rolls on a contacting surface of the linkage projection 75 g. Since this contacting surface of the linkage projection 75 g is a flat surface elongated in the Y-axis direction, the X-axis direction stage 21 can be moved in the Y-axis direction with no driving force in the Y-axis direction being exerted on the first X-axis direction moving member 75 by allowing the transfer roller 21 c to roll on the contacting surface of the linkage projection 75 g.

As shown in FIG. 11, the image stabilizing unit IS is provided with an X-axis drive motor 170 x serving as a drive source (driving device) for driving the CCD image sensor 60 in the X-axis direction and a Y-axis drive motor 170 y serving as a drive source (driving device) for driving the CCD image sensor 60 in the Y-axis direction. The X-axis drive motor 170 x and the Y-axis drive motor 170 y are fixed to a motor bracket 23 bx and a motor bracket 23 by, respectively, which are integrally formed on the stationary holder 23. Each of the X-axis drive motor 170 x and the Y-axis drive motor 170 y is a stepping motor. A drive shaft (rotary shaft) of the X-axis drive motor 170 x is threaded to serve as a feed screw 171 x, and a drive shaft (rotary shaft) of the Y-axis drive motor 170 y is threaded to serve as a feed screw 171 y. The feed screw 171 x is screwed into a female screw hole of an X-axis direction driven nut member 85 x and the feed screw 171 y is screwed into a female screw hole of a Y-axis direction driven nut member 85 y. The X-axis direction driven nut member 85 x is guided linearly in the X-axis direction by the linear groove 76 f, and is in contact with the nut contacting portion 76 e. The Y-axis direction driven nut member 85 y is guided linearly in the Y-axis direction by the linear groove 80 f, and is in contact with the nut contacting portion 80 e. The X-axis direction driven nut member 85 x can be screw-disengaged from either end of the feed screw 171 x, and the Y-axis direction driven nut member 85 y can be screw-disengaged from either end of the feed screw 171 y. A nut-member biasing spring 89 x is positioned between the X-axis direction driven nut member 85 x and the X-axis drive motor 170 x, and a nut-member biasing spring 89 y is positioned between the Y-axis direction driven nut member 85 x and the X-axis drive motor 170 y. Each of the nut-member biasing springs 89 x and 89 y is a compression coil spring. The nut-member biasing springs 89 x and 89 y are loosely fitted on the feed screws 171 x and 171 y, respectively, in a compressed state. The nut-member biasing spring 89 x biases the X-axis direction driven nut member 85 x in a direction to bring the X-axis direction driven nut member 85 x back into screw engagement with the X-axis drive motor 170 x in the case where the X-axis direction driven nut member 85 x is disengaged from the X-axis drive motor 170 x toward the X-axis drive motor 170 x side. Likewise, the nut-member biasing spring 89 y biases the Y-axis direction driven nut member 85 y in a direction to bring the Y-axis direction driven nut member 85 y back into screw engagement with the Y-axis drive motor 170 y in the case where the Y-axis direction driven nut member 85 y is disengaged from the Y-axis drive motor 170 y toward the Y-axis drive motor 170 y side.

FIG. 24 schematically shows the structure of the image stabilizing unit IS, viewed from the rear of the digital camera 200. Note that the relative position between the rotation prevention rod 78 and the pair of guide pins 76 c, etc., are different from those shown in FIGS. 7 through 23 for the purpose of illustration. As can be understood from this schematic diagram, in the driving mechanism for driving the CCD image sensor 60 in the X-axis direction, the first X-axis direction moving member 75 and the second X-axis direction moving member 76 are coupled to each other resiliently by the biasing force of the extension joining spring 81 x with the movement limit lug 75 a and the movement limit lug 75 b in contact with the movement limit lug 76 a and the movement limit lug 76 b, respectively. The biasing force of the X-axis direction stage biasing spring 87 x is exerted on the first X-axis direction moving member 75 via the transfer roller 21 c, which is in contact with the linkage projection 75 g. Although the biasing force of the X-axis direction stage biasing spring 87 x is exerted on the first X-axis direction moving member 75 leftward as viewed in FIG. 24, i.e., in a direction to disengage the movement limit lugs 75 a and 75 b from the movement limit lugs 76 a and 76 b, respectively, the biasing force (spring force) of the extension joining spring 81 x is predetermined to be greater than that of the X-axis direction stage biasing spring 87 x. Therefore, the first X-axis direction moving member 75 and the second X-axis direction moving member 76 are collectively biased leftward as viewed in FIG. 24 while maintaining the movement limit lugs 75 a and 75 b in resilient contact with the movement limit lugs 76 a and 76 b, respectively. Since the leftward movement of the second X-axis direction moving member 76 is limited by the engagement of the nut contacting portion 76 e with the X-axis direction driven nut member 85 x, the position of the X-axis direction driven nut member 85 x serves as a reference position for each of the first X-axis direction moving member 75 and the second X-axis direction moving member 76 in the X-axis direction. As can be seen in FIG. 24, the end of the feed screw 171 x extends through a through-hole (see FIGS. 14 and 15) formed on the nut contacting portion 76 e so as not to interfere therewith.

Driving the X-axis drive motor 170 x to rotate the drive shaft thereof (the feed screw 171 x) causes the X-axis direction driven nut member 85 x, that is screw-engaged with the feed screw 171 x, to move linearly in the X-axis direction, thus causing the relative position between the first X-axis direction moving member 75 and the second X-axis direction moving member 76 in the X-axis direction to vary. For instance, if moved rightward with respect to the view shown in FIG. 24, the X-axis direction driven nut member 85 x presses the nut contacting portion 76 e in the same direction to thereby integrally move the first X-axis direction moving member 75 and the second X-axis direction moving member 76 rightward as viewed in FIG. 24 against the spring force of the X-axis direction stage biasing spring 87 x. If the first X-axis direction moving member 75 is moved rightward with respect to the view shown in FIG. 24, the linkage projection 75 g presses the transfer roller 21 c in the same direction to thereby move the X-axis direction stage 21 rightward as viewed in FIG. 24. Conversely, if the X-axis direction driven nut member 85 x is moved leftward as viewed in FIG. 24, the first X-axis direction moving member 75 and the second X-axis direction moving member 76 follow the X-axis direction driven nut member 85 x to integrally move leftward as viewed in FIG. 24 by the biasing force of the X-axis direction stage biasing spring 87 x. At this time, the X-axis direction stage 21 follows the first X-axis direction moving member 75 to move leftward as viewed in FIG. 24 by the biasing force of the X-axis direction stage biasing spring 87 x. The linkage projection 75 g and the transfer roller 21 c are maintained in contact with each other at all times by the biasing force of the X-axis direction stage biasing spring 87 x.

In the driving mechanism for driving the CCD image sensor 60 in the Y-axis direction, the Y-axis direction moving stage 71 and the Y-axis direction moving member 80 are resiliently coupled to each other via the extension joining spring 81 y with the movement limit lugs 71 c and 71 d being in contact with the movement limit lugs 80 a and 80 b, respectively. Although the Y-axis direction moving stage 71 is biased downward as viewed in FIG. 24 by the spring force of the Y-axis direction stage biasing spring 87 y, i.e., in a direction to disengage the movement limit lugs 71 c and 71 d from the movement limit lugs 80 a and 80 b, respectively, the biasing force (spring force) of the extension joining spring 81 y is predetermined to be greater than that of the Y-axis direction stage biasing spring 87 y. Therefore, the Y-axis direction moving stage 71 and the Y-axis direction moving member 80 are collectively biased downward while maintaining the movement limit lugs 71 c and 71 d in resilient contact with the movement limit lugs 80 a and 80 b, respectively. Since the downward movement of the Y-axis direction moving member 80 is limited by the engagement of the nut contacting portion 80 e with the Y-axis direction driven nut member 85 y, the position of the Y-axis direction driven nut member 85 y serves as a reference position for each of the Y-axis direction moving stage 71 and the Y-axis direction moving member 80 in the Y-axis direction. As can be seen in FIG. 24, the end of the feed screw 171 y extends through a through-hole (see FIGS. 16 and 17) formed on the nut contacting portion 80 e so as not to interfere therewith.

Driving the Y-axis drive motor 170 y to rotate the drive shaft thereof (the feed screw 171 y) causes the Y-axis direction driven nut member 85 y, that is screw-engaged with the feed screw 171 y, to move linearly in the Y-axis direction, thus causing the relative position between the Y-axis direction moving stage 71 and the Y-axis direction moving member 80 in the Y-axis direction to vary. For instance, if the Y-axis direction driven nut member 85 y is moved upward as viewed in FIG. 24, the Y-axis direction driven nut member 85 y presses the nut contacting portion 80 e in the same direction to thereby integrally move the Y-axis direction moving stage 71 and the Y-axis direction moving member 80 upward with respect to the view shown in FIG. 24 against the spring force of the Y-axis direction stage biasing spring 87 y. Conversely, if the Y-axis direction driven nut member 85 y is moved downward with respect to the view shown in FIG. 24, the Y-axis direction moving stage 71 and the Y-axis direction moving member 80 follow the Y-axis direction driven nut member 85 y to integrally move downward by the biasing force of the Y-axis direction stage biasing spring 87 y.

When the Y-axis direction moving stage 71 moves in the Y-axis direction, the X-axis direction stage 21 that is supported by the Y-axis direction moving stage 71 thereon moves together with the Y-axis direction moving stage 71. On the other hand, when the X-axis direction stage 21 moves together with the Y-axis direction moving stage 71 vertically in the Y-axis direction, the contacting point between the transfer roller 21 c and the contacting surface of the linkage projection 75 g varies because the first X-axis direction moving member 75, with which the transfer roller 21 c is in contact, does not move in the Y-axis direction. At this time, the transfer roller 21 c rolls on the contacting surface of the linkage projection 75 g, so that the X-axis direction stage 21 can be moved in the Y-axis direction with no driving force in the Y-axis direction being exerted on the first X-axis direction moving member 75.

According to the above described structure of the image stabilizing unit IS, the X-axis direction stage 21 can be moved forward and reverse in the X-axis direction by driving the X-axis drive motor 170 x forward and reverse, respectively; and the Y-axis direction moving stage 71, together with the X-axis direction stage 21 that is supported by the Y-axis direction moving stage 71, can be moved forward and reverse in the Y-axis direction by driving the Y-axis drive motor 170 y forward and reverse, respectively.

As shown in FIGS. 14 and 15, the first X-axis direction moving member 75 is provided in the vicinity of the movement limit lug 75 a with a position detection lug 75 i in the shape of a small thin plate. As shown in FIG. 16, the Y-axis direction moving stage 71 is provided in the vicinity of the movement limit lug 71 c with a position detection lug 71 h in the shape of a small thin plate. As shown in FIGS. 18 and 19, the image stabilizing unit IS is provided with a first photo-interrupter 103 and a second photo-interrupter 104. The first photo-interrupter 103 detects the presence of the position detection lug 75 i of the first X-axis direction moving member 75 that passes between mutually facing emitter/receiver elements when the light beam is blocked by the position detection lug 75 i. Likewise, the second photo-interrupter 104 detects the presence of the position detection lug 71 h of the Y-axis direction moving stage 71 that passes between mutually facing emitter/receiver elements when the light beam is blocked by the position detection lug 71 h. The initial position of the first X-axis direction moving member 75 (the X-axis direction stage 21) in the X-axis direction can be detected by detecting the presence of the position detection lug 75 i by the first photo-interrupter 103, while the initial position of the Y-axis direction moving stage 71 in the Y-axis direction can be detected by detecting the presence of the position detection lug 71 h by the second photo-interrupter 104.

As shown in the block diagram in FIG. 25, the digital camera 200 is provided with an X-axis direction gyro sensor (angular velocity sensor) 105 and a Y-axis direction gyro sensor (angular velocity sensor) 106 which detect the angular velocity (angular speed) about two axes (the X-axis and the Y-axis) orthogonal to each other. The magnitude and the direction of camera shake (vibrations) applied to the digital camera 200 are detected by these two gyro sensors 105 and 106. Subsequently, the control circuit 102 determines a moving angle by time-integrating the angular velocity of the camera shake in the two axial directions, detected by the two gyro sensors 105 and 106. Subsequently, the control circuit 102 calculates from the moving angle the moving amounts of the image on a focal plane (imaging surface of the CCD image sensor 60) in the X-axis direction and in the Y-axis direction. The control circuit 102 further calculates the driving amounts and the driving directions of the X-axis direction stage 21 (the first X-axis direction moving member 75 and the second X-axis direction moving member 76) and the Y-axis direction moving stage 71 (the Y-axis direction moving member 80) for the respective axial directions (driving pulses for the X-axis drive motor 170 x and the Y-axis drive motor 170 y) in order to counteract camera shake. Thereupon, the X-axis drive motor 170 x and the Y-axis drive motor 170 y are actuated and the operations thereof are controlled in accordance with the calculated values, which counteract image shake of an object image captured by the CCD image sensor 60. The digital camera 200 can be entered into this image stabilization mode by turning on a photographing mode select switch 107 (see FIG. 25). If the photographing mode select switch 107 is in an OFF state, the image stabilizing capability is deactivated so that a normal photographing operation is performed. Additionally, by operating the photographing mode select switch 107, either a first tracking mode or a second tracking mode can be selected in the image stabilization mode. The image stabilizing capability remains activated by driving the X-axis drive motor 170 x and the Y-axis drive motor 170 y in the first tracking mode, while the image stabilizing capability is activated by driving the X-axis drive motor 170 x and the Y-axis drive motor 170 y only when a photometric switch 108 or a release switch 109 (see FIG. 25) provided in the digital camera 200 is turned ON in the second tracking mode. The photometric switch 108 is turned ON by depressing the shutter button 205 half way, and the release switch 109 is turned ON by fully depressing the shutter button 205.

The above illustrated image stabilizer of the digital camera 200 is provided with a damage-protection structure which absorbs loads and impacts on a driving force transfer mechanism from each of the X-axis drive motor 170 x and the Y-axis drive motor 170 y to the CCD image sensor 60 (the X-axis direction stage 21) to prevent damage to the feed screws 171 x and 171 y and other associated elements. This damage-protection structure is composed of two major components: a first component composed of the first X-axis direction moving member 75 and the second X-axis direction moving member 76 (which are resiliently coupled to each other by the extension joining spring 81 x) in the driving mechanism for driving the CCD image sensor 60 in the X-axis direction; and a second part composed of the Y-axis direction stage 71 and the Y-axis direction moving member 80 (which are resiliently coupled to each other by the extension joining spring 81 y) in the driving mechanism for driving the CCD image sensor 60 in the Y-axis direction.

The driving mechanism for driving the CCD image sensor 60 in the X-axis direction has the capability of protecting itself from damage. This capability will be discussed hereinafter.

For instance, when the X-axis direction driven nut member 85 x is moved rightward with respect to the view shown in FIG. 24 by the X-axis drive motor 170 x, the first X-axis direction moving member 75 and the second X-axis direction moving member 76, which move integrally in a normal state, move relative to each other in the X-axis direction so as to disengage the movement limit lug 75 a and the movement limit lug 76 a (and also the movement limit lug 75 b and the movement limit lug 76 b) from each other against the biasing force of the extension joining spring 81 x in the event of the X-axis direction stage 21 abutting against the Y-axis direction stage 71 upon reaching a mechanical limit of movement of the X-axis direction stage 21 or other causes which interfere with movement of the X-axis direction stage 21. Specifically, the second X-axis direction moving member 76 can solely move rightward in the X-axis direction relative to the first X-axis direction moving member 75 in the case where movement of the first X-axis direction moving member 75, together with the X-axis direction stage 21, is prevented for some reason. This structure makes it possible for the X-axis direction driven nut member 85 x to move along the feed screw 171 x even if the X-axis direction stage 21 becomes immobilized. This prevents excessive loads on the aforementioned driving force transfer mechanism, thus preventing thread jamming between the feed screw 171 x and the X-axis direction driven nut member 85 x and further preventing damage to other associated parts of the driving force transfer mechanism. When the X-axis direction driven nut member 85 x is moved leftward with respect to the view shown in FIG. 24 by the X-axis drive motor 170 x, the X-axis direction driven nut member 85 x moves in a direction away from the nut contacting portion 76 e, and accordingly, the driving force of the X-axis drive motor 170 x does not act on either the first X-axis direction moving member 75 or the second X-axis direction moving member 76; hence, no undue loads are exerted on the driving force transfer mechanism even if movement of the X-axis direction stage 21 is prevented for some reason.

Similar to the driving mechanism for driving the CCD image sensor 60 in the X-axis direction, the driving mechanism for driving the CCD image sensor 60 in the Y-axis direction also has the capability of protecting itself from damage. This capability will be discussed hereinafter.

For instance, when the Y-axis direction driven nut member 85 y is moved upward with respect to the view shown in FIG. 24 by the Y-axis drive motor 170 y, the Y-axis direction moving member 80 and the Y-axis direction moving stage 71, which move integrally in a normal state, move relative to each other in the Y-axis direction to disengage the movement limit lug 71 c and the movement limit lug 80 a (and also the movement limit lug 71 d and the movement limit lug 80 b) away from each other against the biasing force of the extension joining spring 81 y in the event of the Y-axis direction stage 71 abutting against the stationary holder 23 upon reaching a mechanical limit of movement of the Y-axis direction stage 71 or other causes which interfere with movement of the Y-axis direction stage 71 (or the X-axis direction stage 21). Specifically, the Y-axis direction moving member 80 can solely move upward in the Y-axis direction relative to the Y-axis direction moving stage 71 in the case where movement of the Y-axis direction stage 71 is prevented for some reason. This structure makes it possible for the Y-axis direction driven nut member 85 y to move along the feed screw 171 y even if the Y-axis direction stage 71 becomes immobilized. This prevents excessive loads on the aforementioned driving force transfer mechanism, thus preventing thread jamming between the feed screw 171 y and the Y-axis direction driven nut member 85 y and further preventing damage to other associated parts of the driving force transfer mechanism. When the Y-axis direction driven nut member 85 y is moved downward with respect to the view shown in FIG. 24 by the Y-axis drive motor 170 y, the Y-axis direction driven nut member 85 y moves in a direction away from the nut contacting portion 80 e, and accordingly, the driving force of the Y-axis drive motor 170 y does not act on either the Y-axis direction moving member 80 or the Y-axis direction moving stage 71; hence, no undue loads are exerted on the driving force transfer mechanism even if movement of the Y-axis direction stage 71 is prevented for some reason.

As mentioned above, the range of movement (mechanical limits of movement) of the X-axis direction stage 21 is defined by inner peripheral surfaces of the Y-axis direction moving stage 71, while the range of movement (mechanical limits of movement) of the Y-axis direction moving stage 71 is defined by inner peripheral surfaces of the stationary holder 23. It is desirable that the driving force of the X-axis drive motor 170 x be stopped being transferred from the feed screw 171 x to the X-axis direction driven nut member 85 x upon the X-axis direction stage 21 reaching either of the right and left limits of movement thereof, and that the driving force of the Y-axis drive motor 170 y be stopped being transferred from the feed screw 171 y to the Y-axis direction driven nut member 85 y upon the Y-axis direction stage 71 reaching either of the upper and lower limits of movement thereof. However, taking manufacturing tolerances of the associated components into consideration, such an ideal correlation cannot be always achieved. For instance, if the X-axis direction driven nut member 85 x and the feed screw 171 x (or the Y-axis direction driven nut member 85 y and the feed screw 171 y) are still screw-engaged with each other by a sufficient axial length in a state where the X-axis direction stage 21 (or the Y-axis direction stage 71) has reached a mechanical limit of movement thereof, there is a possibility of jamming occurring between the feed screw 171 x and the X-axis direction driven nut member 85 x (or the feed screw 171 y and the Y-axis direction driven nut member 85 y) due to loads placed on each of the X-axis direction driven nut member 85 x and the feed screw 171 x (or the Y-axis direction driven nut member 85 y and the feed screw 171 y) by a further rotation of the X-axis drive motor 170 x (or the Y-axis drive motor 170 y) if the image stabilizer of the digital camera 200 incorporates no damage-protection structure such as the above described damage-protection structure. To prevent this problem from occurring, it is conceivable that the image stabilizing mechanism is constructed so that the X-axis direction driven nut member 85 x (the Y-axis direction driven nut member 85 y) is disengaged from the feed screw 171 x (171 y) to come off upon reaching either end of the feed screw 171 x (171 y) after giving the X-axis direction driven nut member 85 x (the Y-axis direction driven nut member 85 y) a sufficient range of movement on the feed screw 171 x (171 y) so that the X-axis direction stage 21 (the Y-axis direction stage 71) does not reach a mechanical limit of movement thereof easily. However, according to this structure, the range of movement of each of the X-axis direction stage 21 and the Y-axis direction stage 71 is required to be increased more than necessary, which may undesirably increase the size of the whole image stabilizer. Additionally, if the X-axis direction stage 21 or the Y-axis direction stage 71 is jammed accidentally at some intermediate position in the range of movement thereof (i.e., not at either end of the range of movement thereof), heavy loads are put on the screw-engaged portion between the X-axis direction driven nut member 85 x (or the Y-axis direction driven nut member 85 y) and the feed screw 171 x (or 171 y), regardless of the range of movement of the X-axis direction stage 21 or the Y-axis direction stage 71. Conversely, according to the above illustrated embodiment of the image stabilizer, a difference in amount of movement in the X-axis direction between the X-axis direction driven nut member 85 x and the X-axis direction stage 21 is absorbed by intermediate members (i.e., the first X-axis direction moving member 75 and the second X-axis direction moving member 76), while a difference in amount of movement in the Y-axis direction between the Y-axis direction driven nut member 85 y and the X-axis direction stage 21 is absorbed by intermediate members (i.e., the Y-axis direction stage 71 and the Y-axis direction moving member 80); and therefore, the range of movement of each of the X-axis direction stage 21 and the Y-axis direction stage 71 does not need to be increased more than necessary. Moreover, even if the X-axis direction stage 21 or the Y-axis direction stage 71 is jammed accidentally at some intermediate position in the range of movement thereof (i.e., not at either end of the range of movement thereof), no heavy loads are put on the screw-engaged portion between the X-axis direction driven nut member 85 x (or the Y-axis direction driven nut member 85 y) and the feed screw 171 x (or 171 y) because a difference in amount of movement in the X-axis direction between the X-axis direction driven nut member 85 x and the X-axis direction stage 21 (or a difference in amount of movement in the Y-axis direction between the X-axis direction driven nut member 85 y and the Y-axis direction stage 21) is absorbed by the aforementioned intermediate members (the first X-axis direction moving member 75 and the second X-axis direction moving member 76, or the Y-axis direction stage 71 and the Y-axis direction moving member 80). In the present embodiment of the image stabilizer, the maximum amount of relative movement between the first X-axis direction moving member 75 and the second X-axis direction moving member 76 is predetermined to be capable of absorbing any difference in amount of movement between the X-axis direction driven nut member 85 x and the X-axis direction stage 21 wherever each of the X-axis direction driven nut member 85 x and the X-axis direction stage 21 may be positioned in the range of movement thereof. Likewise, the maximum amount of relative movement between the Y-axis direction stage 71 and the Y-axis direction moving member 80 is predetermined to be capable of absorbing any difference in amount of movement between the Y-axis direction driven nut member 85 y and the Y-axis direction stage 71 wherever each of the Y-axis direction driven nut member 85 y and the Y-axis direction stage 71 may be positioned in the range of movement thereof.

A restriction on movement on the X-axis direction stage 21 or the Y-axis direction stage 71 is not the only cause of imposing loads on the driving force transfer mechanism. Since the CCD image sensor 60, that serves as an optical element for counteracting image shake, is supported to be freely movable in the X-axis direction and the Y-axis direction, there is a possibility of the X-axis direction stage 21 (which holds the CCD image sensor 60) or the Y-axis direction stage 71 (which holds the X-axis direction stage 21) being subjected to a force which forces the X-axis direction stage 21 or the Y-axis direction stage 71 to move even though no driving force is applied thereto by the X-axis drive motor 170 x or the Y-axis drive motor 170 y, respectively, in the case where a shock or sudden impact is applied to the digital camera 200 when the digital camera 200 is, e.g., dropped to the ground. Even in such a case, such loads, shock or sudden impact can be securely absorbed in the present embodiment of the image stabilizer.

For instance, if the X-axis direction stage 21 is moved leftward with respect to the view shown in FIG. 24 by an external force other than the driving force of the X-axis drive motor 170 x, the first X-axis direction moving member 75 is pressed in the same direction via the transfer roller 21 c. Since this direction of pressing the first X-axis direction moving member 75 is a direction which disengages the movement limit lugs 75 a and 75 b from the movement limit lugs 76 a and 76 b, respectively, the first X-axis direction moving member 75 can solely move leftward relative to the second X-axis direction moving member 76 against the biasing force of the extension joining spring 81 x. At this time, the first X-axis direction moving member 75 does not mechanically press the second X-axis direction moving member 76, so that only a resilient tensile force of the extension joining spring 81 x acts on the second X-axis direction moving member 76, and accordingly, no excessive force is applied to the X-axis direction driven nut member 85 x from the second X-axis direction moving member 76. If the X-axis direction stage 21 is moved rightward with respect to the view shown in FIG. 24 by an external force other than the driving force of the X-axis drive motor 170 x, the X-axis direction stage 21 moves in a direction to disengage the transfer roller 21 c from the linkage projection 75 g, either the first X-axis direction moving member 75 or the second X-axis direction moving member 76 is subjected to the moving force of the X-axis direction stage 21. Namely, even if the X-axis direction stage 21 is forced to move forward or reverse in the X-axis direction by an external force or the like when the X-axis drive motor 170 x is not in operation, no undue loads are exerted on the screw-engaged portion between the X-axis direction driven nut member 85 x and the feed screw 171 x.

On the other hand, if the Y-axis direction stage 71 is moved downward with respect to the view shown in FIG. 24 by an external force other than the driving force of the Y-axis drive motor 170 y, this moving direction of the Y-axis direction stage 71 is a direction which disengages the movement limit lugs 80 a and 80 b from the movement limit lugs 71 c and 71 d, respectively, and accordingly, the Y-axis direction stage 71 can solely move downward relative to the Y-axis direction moving member 80 against the biasing force of the extension joining spring 81 y. At this time, the Y-axis direction stage 71 does not mechanically press the Y-axis direction moving member 80, so that only a resilient tensile force of the extension joining spring 81 y acts on the Y-axis direction moving member 80, and accordingly, no excessive force is applied to the Y-axis direction driven nut member 85 y from the Y-axis direction moving member 80. If the X-axis direction stage 21 is moved upward with respect to the view shown in FIG. 24 by an external force other than the driving force of the X-axis drive motor 170 x, the Y-axis direction moving member 80 is pressed upward via the engagement between the movement limit lug 80 a and the movement limit lug 71 c and the engagement between the movement limit lug 80 b and the movement limit lug 71 d. At this time, the moving force of the Y-axis direction moving member 80 does not act on the Y-axis direction driven nut member 85 y because this direction of movement of the Y-axis direction moving member 80 is a direction which disengages the nut contacting portion 80 e from the Y-axis direction driven nut member 85 y. Namely, even if the Y-axis direction stage 71 is forced to move forward or reverse in the Y-axis direction by an external force or the like when the Y-axis drive motor 170 y is not in operation, no undue loads are exerted on the screw-engaged portion between the X-axis direction driven nut member 85 y and the feed screw 171 y.

As can be understood from the above description, according to the above illustrated embodiment of the image stabilizer, in either of the following two cases, i.e., the case where a malfunction occurs in the moving operation of the X-axis direction stage 21 and/or the Y-axis direction stage 71 when it is driven by the X-axis drive motor 170 x or the Y-axis drive motor 170 y; and the case where the X-axis direction stage 21 and/or the Y-axis direction stage 71 is forced to move unexpectedly by an external force or the like, such an accidental movement can be absorbed to thereby prevent the driving mechanism for the image-stabilizing optical element from being damaged. Specifically, the image stabilizer is designed so that no heavy loads are put on either of the two screw-engaged portions between the X-axis direction driven nut member 85 x and the feed screw 171 x and between the Y-axis direction driven nut member 85 y and the feed screw 171 y, which produces a high degree of effectiveness of preventing each of these two screw-engaged portions from being damaged. Although it is possible to drive the X-axis direction stage 21 and the Y-axis direction stage 71 with a high degree of precision by narrowing the lead angles of the feed screws 171 x and 171 y, respectively, a narrowing of the lead angle of either feed screw disadvantageously reduces the strength of the feed screw mechanism. However, according to the above illustrated embodiment of the image stabilizer, the lead angle of each feed screw can be narrowed since no heavy loads are applied on either of the aforementioned two screw-engaged portions.

FIGS. 26 through 28 show another embodiment (second embodiment) of the image stabilizing unit IS. In this embodiment, the elements corresponding to those in the previous embodiment (first embodiment) of the image stabilizer IS are designated with like reference numerals. The second embodiment of the image stabilizing unit is the same as the first embodiment of the image stabilizing unit except that one end (left end as viewed in FIG. 28) of the X-axis direction stage biasing spring 87 x is hooked on the Y-axis direction stage 71, not on the stationary holder 23. More specifically, the X-axis direction stage biasing spring 87 x is extended and installed between a spring hook 71 w formed on the Y-axis direction stage 71 and the spring hook 21 v of the X-axis direction stage 21. The same effect as that of the first embodiment of the image stabilizing unit can be obtained in the second embodiment of the image stabilizing unit.

In the above illustrated embodiments, the CCD image sensor 60, the low-pass filter 25 and other associated elements are unitized and this CCD unit is driven when image shake is counteracted. The structure of this CCD unit (image pickup device unit) will be discussed in detail with reference to FIGS. 29 through 40.

As shown in FIGS. 29 through 34, the low-pass filter 25 and the CCD image sensor 60 are held between the X-axis direction moving stage 21 and a CCD retaining plate 61. More specifically, the low-pass filter 25 is in contact with an inner surface of the X-axis direction moving stage 21 at the front opening thereof and the imaging surface of the CCD image sensor 60 is positioned behind the low-pass filter 25 with an annular sealing member 26 held between the low-pass filter 25 and the CCD image sensor 60. The sealing member 26 is made of a resilient material. The CCD image sensor 60, together with a CCD substrate 62, is fixed to a front surface of the CCD retaining plate 61. The CCD substrate 62 is extended to the rear of the CCD retaining plate 61 to be connected to one end of a flexible printed wiring board (hereinafter referred to as a flexible PWB) 90 adopted for image signal transmission. Another end of the flexible PWB 90 is connected to a stationary circuit board (not shown) on which the control circuit 102 is mounted. The CCD substrate 62 and the flexible PWB 90 are integrally formed with each other.

The CCD retaining plate 61 is provided with a front flat portion 61 a and three support lugs 61 b. The front flat portion 61 a is configured to support the CCD image sensor 60 and the CCD substrate 62. Two of the three support lugs 61 b project horizontally in opposite directions while the remaining support lug 61 b projects downwards. The X-axis direction moving stage 21 is provided with three recesses 21 d which are shaped to allow the three support lugs 61 b to be fitted therein, respectively. The three support lugs 61 b are provided with three circular through-holes 61 c which extend through the three support lugs 61 b in a forward/rearward direction, respectively. Three nuts 63 are fixed to the X-axis direction moving stage 21 inside the three recesses 21 d to face the through-holes 61 c, respectively. The X-axis direction moving stage 21 is provided in the vicinity of the three nuts 63 with three spring accommodation recesses 21 e in which three compression coil springs 64 are accommodated, respectively. The two side support lugs 61 b of the front flat portion 61 a are provided below the associated two through-holes 61 c with two positioning holes 61 d, respectively. The X-axis direction moving stage 21 is provided in two of the three recesses 21 d with two positioning projections 21 f which can be engaged in the two positioning holes 61 d, respectively.

The three nuts 63 are made of metal which is a different material from the X-axis direction moving stage 21. Each nut 63 is provided with a hollow cylinder portion 63 a and is further provided at one end of the cylinder portion (cylindrical shaft portion) 63 a with a flange portion 63 b. The three nuts 63 are fixed to the X-axis direction moving stage 21 with the three flange portions 63 b being engaged in three large-diameter holes 21 g formed on the front of the X-axis direction moving stage 21, respectively. The cylinder portion 63 a of each nut 63 extends through the bottom of the associated large-diameter portion 21 g to project rearward therefrom in the optical axis direction. As shown in FIGS. 35 and 36, the outer diameter of the cylinder portion 63 a of each nut 63 is predetermined to be slightly smaller than the inner diameter (opening diameter) of the associated through-hole 61 c of the CCD retaining plate 61. Each nut 63 is provided along the axis of the cylindrical portion 63 a thereof with a female screw hole 63 c so that three CCD adjustment screws 65 are screwed into the three female screw holes 63 c from the ends thereof (from the rear ends thereof in the optical axis direction), respectively. Each CCD adjustment screw 65 is provided with a shaft portion (screw shaft portion) 65 a including a male thread portion thereon which is screw-engaged with the associated female screw hole 63 c, and a head portion 65 b which is greater in diameter than the shaft portion 65 a. Unlike the cylinder portion 63 a, the outer diameter of the head portion 65 b is predetermined to be greater than the inner diameter (opening diameter) of the associated through-hole 61 c.

When the CCD unit is assembled, the CCD retaining plate 61 and the X-axis direction moving stage 21 are brought to approach each other so that the three support lugs 61 b enter the corresponding three recesses 21 d, respectively, with the three compression coil springs 64 inserted into the three spring accommodation recesses 21 e in a compressed state, respectively. Thereupon, the two positioning projections 21 f engage in the two positioning holes 61 d, respectively, which determines the relative position between the X-axis direction moving stage 21 and the CCD image sensor 60. Additionally, bringing the CCD retaining plate 61 and the X-axis direction moving stage 21 closer to each other to some extent causes the ends of the hollow cylinder portions 63 a of the three nuts 63 to enter the three circular through-holes 61 c, respectively, since the outer diameter of the cylinder portion 63 a of each nut 63 is smaller than the inner diameter (opening diameter) of the associated through-hole 61 c as mentioned above.

Subsequently, the shaft portions 65 a of the three CCD adjustment screws 65 are screwed into the female screw holes 63 c of the three nuts 63, respectively. Bringing the X-axis direction moving stage 21 and the CCD retaining plate 61 closer to each other causes the compressed coil springs 64, which are inserted in the three recesses 21 d, to be compressed between the X-axis direction moving stage 21 and the three support lugs 61 b. Due to the resilient force of the compressed coil springs 64 thus compressed, the CCD retaining plate 61 is biased in a direction away from the X-axis direction moving stage 21 (rearwards in the optical axis direction) (see FIG. 37). However, the back surfaces of the head portions 65 b of the three CCD adjustment screws 65 prevent the CCD retaining plate 61 from moving rearward, thus defining the position of the CCD retaining plate 61 in the optical axis direction. Accordingly, the X-axis direction moving stage 21 and the CCD retaining plate 61 are joined together with the CCD image sensor 60 and the low-pass filter 25 held therebetween.

In the CCD unit, in which the X-axis direction moving stage 21 and the CCD retaining plate 61 are thus joined together, the three CCD adjustment screws 65 are arranged dispersively at three different points about the center of the imaging surface of the CCD image sensor 60, and accordingly, the angle (inclination angle/setting angle) of the CCD retaining plate 61 relative to the photographing optical axis Z1, i.e., the angle (inclination angle/setting angle) of the imaging surface of the CCD image sensor 60 relative to the photographing optical axis Z1, can be adjusted by adjusting the tightening amount of each CCD adjustment screw 65. For instance, if the tightening amount of one CCD adjustment screw 65 is increased, the associated head portion 65 b that defines the position of the CCD retaining plate 61 in the optical axis direction moves forward in the optical axis direction. This forward movement of the head portion 65 b causes the associated support lug 61 b which is in contact with the one CCD adjustment screw 65 to be pushed forward. Conversely, if the tightening amount of one CCD adjustment screw 65 is decreased, the associated head portion 65 b moves rearward in the optical axis direction. This rearward movement of the head portion 65 b causes the associated support lug 61 b which is in contact with the one CCD adjustment screw 65 to be pushed rearward by the biasing force of the associated compression coil springs 64. The inclination angle of the CCD image sensor 60 relative to the photographing optical axis Z1 can be adjusted by changing the balance among the tightening amounts of the three CCD adjustment screws 65.

FIGS. 33 and 34 are cross sectional views of the image stabilizing unit IS, respectively showing two different states before and after making adjustments to specific two of the three CCD adjustment screws 65 which are positioned on the horizontally opposite sides of the front flat portion 61 a. In the state shown in FIG. 33, the tightening amounts of these two CCD adjustment screws 65 (the right and left CCD adjustment screws 65) are substantially identical and are not tightened to the maximum (to the limit) relative to the female screw holes 63 c of the associated two nuts 63. FIG. 35 is an enlarged view of one of the right and left CCD adjustment screws 65 (the left CCD adjustment screw 65 as viewed in FIG. 34) and adjacent elements thereof in the state shown in FIG. 33. As can be seen from FIG. 35, the associated support lug 61 b abuts against the back surface of the head portion 65 b of the CCD adjustment screw 65 by the biasing force of the associated compression coil spring 64; however, there is room for the head portion 65 b and the support lug 61 b to be moved forward (downwards as viewed in FIG. 35) by further tightening the CCD adjustment screw 65 since there is still a space between the end of the cylinder portion 63 a and the head portion 65 b.

FIG. 34 illustrates a state in which the left CCD adjustment screw 65 has been tightened to the maximum. As can be seen in the enlarged view of the left CCD adjustment screw 65 and adjacent elements thereof in FIG. 36, the support lug 61 b, which is in contact with the left CCD adjustment screw 65, has been pushed forward from the position shown in FIG. 35 against the biasing force of the compression coil spring 64 to thereby cause the CCD retaining plate 61 and the CCD image sensor 60 to tilt relative to the X-axis direction moving stage 21 (relative to the optical axis direction). In this state, the X-axis direction moving stage 21 is not tilted by the tilting of the CCD image sensor 60; however, the resilient sealing member 26, which is held between the low-pass filter 25 and the CCD image sensor 60, is resiliently deformed by the tilting of the CCD image sensor 60 (see FIG. 34).

As shown in FIG. 36, each CCD adjustment screw 65 can be tightened up until the head portion 65 b comes into contact with the end of the cylinder portion 63 a of the associated nut 63 because the cylinder portions 63 a of the three nuts 63 are inserted in the three circular through-holes 61 c, respectively. In this state, the support lug 61 b is not held so as to be attached between the head portion 65 b of the associated CCD adjustment screw 65 and the bottom of the associated recess 21 d of the X-axis direction moving stage 21, but rather is held without making contact with the bottom of the recess 21 d. Since the support lug 61 b is not held so as to be attached between the head portion 65 b of the associated CCD adjustment screw 65 and the bottom of the associated recess 21 d, the CCD retaining plate 61 is not prevented from tilting even if the CCD adjustment screw 65 is tightened to the maximum when the tightening amount of either of the remaining two CCD adjustment screws 65 is changed. Accordingly, the entire range of axial movement of the shaft portion 65 a of each CCD adjustment screw 65 relative to the associated nut 63 (the female screw hole 63 c thereof) can be used for making an adjustment (inclination angle adjustment) to the angle of the CCD retaining plate 61 relative to the photographing optical axis Z1.

The CCD unit is completed by fixing a movable plate (image-pickup-device holding member/flexible printed wiring board support member) 91 to the back of the X-axis direction moving stage 21 after the X-axis direction moving stage 21 and the CCD retaining plate 61 are joined together (see FIGS. 31 and 32). The movable plate 91 is a flat plate member which lies in a plane substantially parallel to a plane in which the CCD image sensor 60 is driven, i.e., substantially parallel to an X-axis and Y-axis plane defined by both the X-axis direction and the Y-axis direction. The X-axis direction moving stage 21 is provided with a pair of engaging holes 21 h, a screw hole 21 i and a positioning projection 21 k. The movable plate 91 is provided with a pair of locking lugs 91 a, a through-hole 91 b and a positioning hole 91 c which are engaged in the pair of engaging holes 21 h, the screw hole 21 i and the positioning projection 21 k of the X-axis direction moving stage 21, respectively. The movable plate 91 is secured to the X-axis direction moving stage 21 by a set screw 92 which is screwed into the screw hole 21 i of the X-axis direction moving stage 21 in a state where the ends of the pair of locking lugs 91 a have been engaged in the pair of engaging holes 21 h and where the positioning projection 21 k has been engaged in the positioning hole 91 c (see FIG. 32).

The CCD unit is supported by the above described driving mechanisms for driving the CCD image sensor 60 in the X-axis direction and the Y-axis direction constituting the image stabilizing unit IS. The image stabilizing unit IS is provided with a stationary cover 93 which covers the back of the image stabilizing unit IS for projection thereof. The stationary cover 93 is a flat plate member which lies in a plane substantially parallel to a plane in which the CCD image sensor 60 is driven, i.e., substantially parallel to an X-axis and Y-axis plane defined by both the X-axis direction and the Y-axis direction, and accordingly, the stationary cover 93 is substantially parallel to the moving plate 91. As shown in FIG. 29, the stationary cover 93 is provided with four through-holes 93 a arranged dispersively in the vicinity of the outer edge of the stationary cover 93, and is further provided around the four through-holes 93 a with four ring-shaped abutting surfaces 93 b, respectively. The four ring-shaped abutting surfaces 93 b substantially lies in one plane. The stationary cover 93 is further provided with three access holes (through-holes) 93 c and two positioning holes (through-holes) 93 d.

FIGS. 8 and 9 show the image stabilizing unit IS from which the movable plate 91 and the stationary cover 93 are removed. As can be understood from FIGS. 8 and 9, the stationary holder 23 is provided, on the back thereof at four positions corresponding to the four through-holes 93 a of the stationary cover 93, with four screw holes 23 c, respectively, and is further provided around the four screw holes 23 c with four abutting surfaces 23 d with which the four abutting surfaces 93 b of the stationary cover 93 are in contact, respectively. The stationary holder 23 is provided with two positioning projections 23 e which are engageable in the two positioning holes 93 d, respectively.

When the stationary cover 93 is mounted to the stationary holder 23, the two positioning projections 23 e are brought into engagement with the two positioning holes 93 d, respectively. Thereupon, the four abutting surfaces 93 b of the stationary cover 93 come in contact with the corresponding four abutting surfaces 23 d of the stationary holder 23, respectively, so that the four through-holes 93 a and the four screw holes 23 c are aligned. Thereafter, as shown in FIG. 38, the stationary cover 93 is fastened to the stationary holder 23 using four set screws 94 which are screwed into the screw holes 23 c of the stationary holder 23 through the through-holes 93 a of the stationary cover 93. As shown FIG. 38, the head portions 65 b of the three CCD adjustment screws 65 are exposed through the three access holes 93 c of the stationary cover 93 in a state where the movable plate 91 and the stationary cover 93 are mounted, and accordingly, the above described inclination angle adjustment operation for adjusting the angle of the CCD image sensor 60 relative to the photographing optical axis Z1 can be carried out without dismounting the movable plate 91 or the stationary plate 93.

The control circuit 102 is mounted on the aforementioned stationary circuit board (not shown) that is provided in the camera body 202, and this stationary circuit board and the CCD substrate 62 are electrically connected to each other via the flexible PWB 90 as mentioned above. As shown in FIGS. 2, 3, 12 and 40, the flexible PWB 90 is provided with a stationary CCD-connecting portion 90 a, a U-shaped folded portion 90 v 1, a first vertical flat portion 90 b, a bent portion 90 v 2, a first horizontal flat portion 90 c, a U-shaped folded portion 90 v 3, a second horizontal flat portion 90 d, a bent portion 90 v 4, a second vertical flat portion 90 e, a laterally elongated portion 90 f and a connector portion 90 g. The stationary CCD-connecting portion 90 a is formed integral with the CCD substrate 62 in the back of the CCD retaining plate 61. A bottom end portion of the stationary CCD-connecting portion 90 a is folded back upon itself to extend upward to form the U-shaped folded portion 90 v 1. The first vertical flat portion 90 b is elongated upward in the Y-axis direction from the U-shaped folded portion 90 v 1. An upper end of the first vertical flat portion 90 b is bent forward at a substantially right angle to form the bent portion 90 v 2. The first horizontal flat portion 90 c is elongated forward from the bent portion 90 v 2 above the zoom motor 150. A front end of the first horizontal flat portion 90 c is folded over upon itself by substantially 180 degrees to extend rearward to form the U-shaped folded portion 90 v 3. The second horizontal flat portion 90 d is elongated rearward from the U-shaped folded portion 90 v 3. A rear end portion of the second horizontal flat portion 90 d is bent downward at a substantially right angle to form the bent portion 90 v 4. The second vertical flat portion 90 e is elongated downward in the Y-axis direction from the bent portion 90 v 4. The laterally elongated portion 90 f is laterally elongated in the X-axis direction from the lower end of the second vertical flat portion 90 e. The connector portion 90 g is formed at one end (right end as viewed in FIG. 38) of the laterally elongated portion 90 f to be attached to the aforementioned stationary circuit board (not shown) on which the control circuit 102 is mounted. The first vertical flat portion 90 b and the second vertical flat portion 90 e are substantially parallel to each other and the lengthwise direction of each of the first vertical flat portion 90 b and the second vertical flat portion 90 e is substantially parallel to the Y-axis direction. The first horizontal flat portion 90 c and the second horizontal flat portion 90 d are substantially parallel to each other and the lengthwise direction of each of the first horizontal flat portion 90 c and the second horizontal flat portion 90 d is substantially parallel to the photographing optical axis Z1. Note that the flexible PWB 90 and the CCD substrate 62 are not shown in the rear perspective views in FIGS. 8, 9, 19, 21 and 23 to expose the back of the front flat portion 61 a of the CCD retaining plate 61.

As shown in FIG. 40, the movable plate 91 is fixed to the X-axis direction moving stage 21 to be spaced from the front flat portion 61 a of the CCD retaining plate 61 in the optical axis direction to form a flexible PWB insertion space S1 between the CCD retaining plate 61 and the movable plate 91. In addition, another flexible PWB insertion space S2 is formed between the stationary cover 93 and the LCD panel 20 that is positioned behind the stationary cover 93. The U-shaped folded portion 90 v 1 of flexible PWB 90, which has a U-shape in cross section, is positioned in the flexible PWB insertion space S1 so that the stationary CCD-connecting portion 90 a and the first vertical flat portion 90 b are positioned at the front and the rear of the flexible PWB insertion space S1, respectively. The stationary CCD-connecting portion 90 a is fixed to the back of the CCD retaining plate 61. On the other hand, the first vertical flat portion 90 b is in contact (surface contact) with a front surface of the movable plate 91 and guided by the movable plate 91 in a direction to extend from the U-shaped folded portion 90 v 1 to the bent portion 90 v 2. The second vertical flat portion 90 e and the laterally elongated portion 90 f, which extend behind the first vertical flat portion 90 b via the first horizontal flat portion 90 c and the second horizontal flat portion 90 d, extend in the flexible PWB insertion space S2 and are supported by a back surface of the stationary cover 93. Each of the second vertical flat portion 90 e and the laterally elongated portion 90 f is partly fixed to the back of the stationary cover 93 using a fixing device such as an adhesive double coated tape.

In this flexible printed wiring board arrangement, the movable plate 91 is arranged at a position in the optical axis direction between the CCD retaining plate 61, which supports one end of the flexible PWB 90 (the CCD substrate 62), and the stationary cover 93 that serves as a stationary support portion. As shown in FIG. 40, a part (stationary part) of the flexible PWB 90 which includes the second vertical flat portion 90 e, the laterally elongated portion 90 f and the connector portion 90 g is fixed to the back of the stationary cover 93 in the optical axis direction and supported thereby, and the movable plate 91 is positioned so as to cover another part (movable part) of the flexible PWB 90 which extends vertically in front of the stationary cover 23, thus preventing the other part of the flexible printed PWB 90 and the stationary cover 93 from touching each other. Accordingly, the movable plate 91 serves as a protective member which prevents the flexible PWB 90 (except the aforementioned stationary portion thereof that is positioned behind the stationary cover 93) from touching adjacent stationary members such as the stationary cover 93 and the stationary holder 23. In general, if a flexible PWB (90) comes in contact with any adjacent stationary members when following movements of a movable member while being elastically deformed, friction occurs between the flexible PWB (90) and such adjacent members, and this friction may cause resistance to movements of such a movable member. However, according to the present embodiment of the flexible printed wiring board arrangement, providing the image stabilizing unit IS with the movable plate 91 makes it possible to prevent the aforementioned movable part of the flexible PWB 90 from touching adjacent stationary members to thereby prevent such friction from occurring. Additionally, a part of the first vertical flat portion 90 b of the flexible PWB 90 is in surface contact with the front surface of the movable plate 91. Since the movable plate 91 is a movable member which is driven integrally with the CCD image sensor 60 in the X-axis direction and the Y-axis direction, no excessive friction occurs between the first vertical flat portion 90 b and the movable plate 91 in the range of this surface contact when the CCD image sensor 60 is driven to counteract image shake. In this manner, the movable plate 91 serves as a protective member which prevents the aforementioned movable part of the flexible PWB 90 from touching adjacent stationary members and also serves as a movable support member which provides a bending-resistance property to the flexible PWB 90 while preventing excessive friction from occurring. Accordingly, the stability of the flexible PWB 90 is improved and therefore the CCD image sensor 60 (CCD unit) can be driven with a higher degree of precision under less load.

In the above described inclination angle adjustment operation for adjusting the angle of the CCD image sensor 60, the CCD retaining plate 61 is tilted relative to the X-axis direction moving stage 21 and the movable plate 91. A variation of the holding angle of the CCD retaining plate 61 produces a force which twists the flexible PWB 90 via the portion of thereof fixed to the CCD retaining plate 61. Since the flexible PWB 90 itself has elasticity, the flexible PWB 90 can cope with such twisting force by being elastically deformed. However, in the case where this elastically deformed portion of the flexible PWB 90 touches an adjacent stationary member, there is a possibility of excessive loads on movements of the CCD image sensor 60 (CCD unit) being produced when the flexible PWB 90 follows movements of the CCD image sensor 60 in the image stabilizing operation. In the present embodiment of the flexible printed wiring board arrangement, although the U-shaped folded portion 90 v 1, which is positioned in the flexible PWB insertion space S1 between the CCD retaining plate 61 and the movable plate 91, is twisted to be elastically deformed when the angle of the CCD image sensor 60 relative to the photographing optical axis Z1 is adjusted as shown in FIG. 34, the twisted portion of the flexible PWB 90 which extends from the first vertical flat portion 90 b onward is restrained because the first vertical flat portion 90 b that follows the folded portion 90 v 1 is in surface contact with a front surface of the movable plate 91 to be supported thereby. In other words, the angle of the CCD retaining plate 61 relative to the photographing optical axis Z1 is adjusted in the space (the flexible PWB insertion space S1) between the X-axis direction moving stage 21 and the movable plate 91, while the flexible PWB 90 that extends from the CCD image sensor 60 is supported by a surface of the movable plate 91 which faces the CCD retaining plate 61. Consequently, the twist of the flexible PWB 90 which is produced by an inclination angle adjustment made to the CCD image sensor 60 is absorbed within the CCD unit (at the folded portion 90 v 1) that is held between the X-axis direction moving stage 21 and the movable plate 91, so that no deformation of the flexible PWB 90, which may cause an increase in load on the movement of the CCD image sensor 60, remains in the portion thereof that extends outwards from the CCD unit. Namely, making an adjustment to the angle of the CCD image sensor 60 relative to the photographing optical axis Z1 has no adverse influence on the driving accuracy of the CCD unit.

The first vertical flat portion 90 b of the flexible PWB 90 is fixed to the movable plate 91 in the vicinity of the upper end thereof. The fixing position (fixing range) on the movable plate 91, to which the first vertical flat portion 90 b of the flexible PWB 90 is fixed, is represented by “H1” shown in FIGS. 40 and 41.

As shown in FIGS. 40 and 41, in the driving mechanism for driving the CCD image sensor 60 (which serves as an optical element for counteracting image shake) in the X-axis direction, the X-axis direction guide rod 72, which serves as a guide device for guiding the X-axis direction stage 21 linearly in the X-axis direction, and the transfer roller 21 c, which serves as a force receiving portion that receives a driving force from the X-axis drive motor 170 x (the first X-axis direction moving member 75) in the X-axis direction stage 21, are arranged to be mutually different in position in the Y-axis direction. Due to this arrangement, upon the transfer roller 21 c being pressed by the linkage projection 75 g of the first X-axis direction moving member 75 in a direction against the biasing force of the X-axis direction stage biasing spring 87 x (rightward as viewed in FIG. 41), the X-axis direction stage 21 is acted upon by a turning moment about the portion of engagement between the X-axis direction guide rod 72 and the guide hole 21 a upon a moving force which moves the X-axis direction stage 21 in the X-axis direction being applied to the X-axis direction stage 21 that is guided linearly by the X-axis direction guide rod 72.

The movable plate 91 together with the X-axis direction moving stage 21 constitutes a holding member (image-pickup-device holding member) for holding the CCD image sensor 60. When the movable plate 91 moves with the X-axis direction moving stage 21 in the X-axis direction, the moving force thereof is transferred to the fixing position H1 on the movable plate 91, to which the flexible PWB 90 is fixed. Thereupon, with the fixing position H1 as a power point, an X-axis direction guide portion consisting of the X-axis direction guide rod 72 and the guide hole 21 a is acted upon by a turning moment by the flexible PWB 90. More specifically, the X-axis direction moving stage 21 is acted upon by a moment which rotates the X-axis direction moving stage 21 by the flexible PWB 90 with the following three points (1), (2) and (3) serving as a power point, a fulcrum and a point of application in the principle of leverage, respectively: (1) the fixing position H1 on the holding member (which consists of the X-axis direction moving stage 21 and the movable plate 91) for holding the CCD image sensor 60, to which the flexible PWB 90 is fixed, (2) the transfer roller 21 c that serves as the aforementioned force receiving portion via which the X-axis drive motor 170 x applies a driving force to this holding member, and (3) a combination of the X-axis direction guide rod 72 and the guide hole 21 a that serves as a guide device for guiding the X-axis direction stage 21 linearly in the X-axis direction.

In the case where the distance from the transfer roller 21 c (which serves as a fulcrum) to the X-axis direction guide rod 72 and the guide hole 21 a (which serve as a point of application) in the Y-axis direction is represented by “A” (shown in FIG. 41) and where the distance from the fixing position H1 (which serves as a power point) to the transfer roller 21 c (which serves as a fulcrum) in the Y-axis direction is represented by “B” (shown in FIG. 41), the positional relationship among the transfer roller 21 c, the combination of the X-axis direction guide rod 72 and the guide hole 21 a, and the fixing position H1 is predetermined so that the distance A becomes greater than the distance B (i.e., A>B). By making the distance B smaller than the distance A, loads on the point of application can be reduced due to the principle of leverage. Namely, a resistance to movements of the flexible PWB 90 when the CCD image sensor 60 is driven to counteract image shake in the X-axis direction can be reduced, so that a deleterious moment such as a bending moment or a torsional moment can be substantially prevented from occurring.

As an example to be compared with the image stabilizing unit shown in FIG. 41, FIG. 42 shows a comparative example of image stabilizing unit wherein a flexible PWB 90′ (which corresponds to the flexible PWB 90) extends downward, toward the rotation prevention rod 74, from the CCD image sensor 60. In this comparative example shown in FIG. 42, the flexible PWB 90′ is fixed to a holding member for holding the CCD image sensor 60 (which is either the X-axis direction stage 21, or a member such as the movable plate 91 that is fixed to the X-axis direction stage 21 to move with the X-axis direction stage 21) at a fixing position H1′. The distance from the center of the CCD image sensor 60 to the fixing position H1′ in the Y-axis direction is substantially identical to the distance from the center of the CCD image sensor 60 to the fixing position H1 in the Y-axis direction in the embodiment shown in FIG. 41. Contrary to the previous embodiment, in the comparative example shown in FIG. 42, a distance B′ (shown in FIG. 42) from the fixing position H1′ (which serves as a power point) to the transfer roller 21 c (which serves as a fulcrum) in the Y-axis direction is greater than the distance A from the transfer roller 21 c (which serves as a fulcrum) to the X-axis direction guide rod 72 and the guide hole 21 a (which serve as a point of application) in the Y-axis direction (i.e., A<B′). Upon comparing the comparative example shown in FIG. 42 with the embodiment shown in FIG. 41, a force acting on the X-axis direction guide portion that serves as a point of application in the comparative example shown in FIG. 42 becomes greater than that in the embodiment shown in FIG. 41 by the principle of leverage if the same magnitude of load is exerted on the fixing positions H1 and H1′, each of which serves as a power point. In other words, considering the load on movements of the CCD image sensor 60 by the flexible PWBs 90 and 90′, the embodiment of the image stabilizing unit shown in FIG. 41 can curb the occurrence of a deleterious moment such as a bending moment or a torsional moment in the X-axis direction more efficiently than the comparative example shown in FIG. 42.

In the embodiment of the image stabilizing unit shown in FIG. 41, the X-axis direction guide rod 72 and the guide hole 21 a (which serve as a point of application), the fixing position H1 (which serves as a power point) and the transfer roller 21 c (which serves as a fulcrum) are arranged in that order in the Y-axis direction from the side closer to the center of the CCD image sensor 60. However, it is possible that this positional relationship among the point of application, the power point and the fulcrum be determined differently from that in the image stabilizing unit shown in FIG. 41 so long as the aforementioned relational expression “A>B” is satisfied. For instance, it is possible that the fixing position H1 on the holding member for holding the CCD image sensor 60, to which the flexible PWB 90 is fixed, be replaced by a fixing position H2 shown in FIG. 41. In this case also, the distance from the fixing position H2 to the transfer roller 21 c is predetermined to be smaller than the distance A from the X-axis direction guide rod 72 and the guide hole 21 a to the transfer roller 21 c in the Y-axis direction.

As another embodiment (third embodiment) of image stabilizing unit, the relative position as shown in FIG. 43 is also possible. The image stabilizing unit shown in FIG. 43 is different from the image stabilizing unit shown in FIG. 41 in that a transfer roller 121 c (fulcrum; which corresponds to the transfer roller 21 c) shown in FIG. 43 that serves as a force receiving portion to which a moving force is transferred from a linkage projection 175 g (which corresponds to the linkage projection 75 g) is located at a position closer to the CCD image sensor 60 than the transfer roller 21 c shown in FIG. 41 in the Y-axis direction, and that the X-axis direction guide portion that consists of the X-axis direction guide rod 72 and the guide hole 121 a is located at a position farther from the CCD image sensor 60 than the transfer roller 121 c in the Y-axis direction. Although not shown in FIG. 43, a movable plate similar to the movable plate 91 provided in the previous embodiments of the image stabilizing units is fixed to the back of the X-axis direction stage 21, and a portion of a flexible PWB 190 (which corresponds to the flexible PWB 90) is fixed to this movable plate to be supported thereby. By setting the fixing position on this movable plate to which the flexible PWB 190 is fixed to a fixing position H3 (see FIG. 43) between an X-axis direction guide rod 172 (which corresponds to the X-axis direction guide rod 72) and the transfer roller 121 c, the aforementioned relational expression “A>B” can be satisfied in the positional relationship among the power point, the fulcrum and the point of application in the principle of leverage. Additionally, it is possible that the fixing position H3 be replaced by a fixing position H4 shown in FIG. 43. In this case, the distance from the fixing position H4 to the transfer roller 121 c is predetermined to be smaller than the distance A from the X-axis direction guide rod 172 and a guide hole 121 a (which corresponds to the guide hole 21 a) to the transfer roller 121 c in the Y-axis direction.

Although the present invention is applied to the driving mechanism for driving the CCD image sensor 60 in the X-axis direction in each of the above illustrated embodiments of the image stabilizing units, the present invention can also be applied to the driving mechanism for driving the CCD image sensor 60 in the Y-axis direction if the length-width orientation is reversed. FIG. 44 shows another embodiment (fourth embodiment) of the image stabilizing unit, wherein a flexible PWB 290 (which corresponds to the flexible PWB 90) which extends from the CCD image sensor 60 is extended leftward as viewed in FIG. 44, toward the Y-axis direction guide rod 73, in a plane orthogonal to the photographing optical axis Z1. In the driving mechanism for driving the CCD image sensor 60 in the Y-axis direction, the Y-axis direction guide rod 73 and the guide hole 71 a serves as a guide device for guiding the Y-axis direction stage 71 linearly in the Y-axis direction, and the spring hook 71 g serves as a force receiving portion on the Y-axis direction stage 70 to which the driving force of the Y-axis drive motor 170 y is transferred via the extension joining spring 81 y when the Y-axis direction moving member 80 is moved upward by the Y-axis drive motor 170 y. The Y-axis direction guide rod 73 and the guide hole 71 a, and the spring hook 71 g become a point of application and a fulcrum of the turning moment, respectively, which is applied to the Y-axis direction stage 71 from the flexible PWB 290 when the Y-axis direction stage 71 is driven in the Y-axis direction. The flexible PWB 290 is fixed to the Y-axis direction stage 71 (or a member which is moved with the Y-axis direction stage 71 in the Y-axis direction) at a fixing position H5 shown in FIG. 44. The Y-axis direction stage 71 (or such a member moved with the Y-axis direction stage 71) constitutes a holding member (image-pickup-device holding member) for holding the CCD image sensor 60 in this embodiment shown in FIG. 44. A distance A from the Y-axis direction guide rod 73 and the guide hole 71 a to the spring hook 71 g in the X-axis direction (which corresponds to the distance A shown in FIG. 41) is predetermined to be greater than a distance B from the fixing position H5 to the spring hook 71 g (which corresponds to the distance B shown in FIG. 41) (A>B), similar to the embodiment of the image stabilizing unit shown in FIG. 41. Therefore, a resistance to movements of the flexible PWB 290 when the CCD image sensor 60 is driven to counteract image shake in the Y-axis direction can be reduced by the principle of leverage. Note that the fixing position on the Y-axis direction stage 71 (or a member which is moved with the Y-axis direction stage 71 in the Y-axis direction) to which the flexible PWB 290 is fixed is not limited solely to the fixing position H5 so long as the aforementioned relational expression “A>B” is satisfied.

As an example to be compared with the image stabilizing unit shown in FIG. 44, FIG. 45 shows a comparative example of image stabilizing unit wherein a flexible PWB 290′ (which corresponds to the flexible PWB 290) extends rightward, toward the rotation prevention rod 79, from the CCD image sensor 60. In this comparative example shown in FIG. 45, the flexible PWB 290′ is fixed to the Y-axis direction stage 71 (or a member which is moved with the Y-axis direction stage 71 in the Y-axis direction) at a fixing position H5′. The distance from the center of the CCD image sensor 60 to the fixing position H5′ in the X-axis direction is substantially identical to the distance from the center of the CCD image sensor 60 to the fixing position H5 in the X-axis direction in the embodiment shown in FIG. 44. Contrary to the embodiment shown in FIG. 44, in the comparative example shown in FIG. 45, a distance B′ (shown in FIG. 45) from the fixing position H5′ (which serves as a power point) to the spring hook 71 g (which serves as a fulcrum) in the X-axis direction is greater than the distance A from the spring hook 71 g (which serves as a fulcrum) to the Y-axis direction guide rod 73 and the guide hole 71 a (which serve as a point of application) in the X-axis direction (namely, A<B′). Upon comparing the comparative example shown in FIG. 45 with the embodiment shown in FIG. 44, a force acting on a Y-axis direction guide portion that serves as a point of application in the comparative example shown in FIG. 45 is greater than that in the embodiment shown in FIG. 44 by the principle of leverage if the same magnitude of load is exerted on the fixing positions H5 and H5′ to which the flexible PWBs 290 and 290′ are fixed, respectively, each of which serves as a power point. In other words, considering the load on movements of the CCD image sensor 60 by the flexible PWBs 290 and 290′, the embodiment of the image stabilizing unit shown in FIG. 44 can curb the occurrence of a deleterious moment such as a bending moment or a torsional moment in the Y-axis direction considerable more than the comparative example shown in FIG. 45.

As can be understood from the above description, according to the image stabilizer to which the present invention is applied, the occurrence of a deleterious moment such as a bending moment or a torsional moment that occurs in the image stabilizing operation can be considerably suppressed, to thereby make it possible to move an image pickup device serving as an image stabilizing optical element with a high degree of precision.

Although the image stabilizing units shown in FIGS. 41, 43 and 44 that have been referred to in the descriptions of the present invention are of a type in which one end of the X-axis direction stage biasing spring 87 x is supported by the stationary holder 23, effects similar to those obtained in this type of image stabilizing unit can also be obtained in another type of image stabilizing unit shown in FIGS. 26 through 28 in which the X-axis direction stage biasing spring 87 x is engaged with the spring hook 71 w of the Y-axis direction stage 71.

Although the present invention has been described based on the above illustrated embodiments, the present invention is not limited solely to these particular embodiments. For instance, although the flexible PWB 90 includes a forward-extending portion which is composed of the first horizontal flat portion 90 c, the U-shaped folded portion 90 v 3 and the second horizontal flat portion 90 d, and this forward-extending portion contributes to a reduction of a resistance to movements of the flexible PWB 90 when the CCD image sensor 60 is driven, it is possible that this forward-extending portion be omitted in the flexible printed wiring board arrangement of the present invention.

Although the X-axis direction stage 21 is configured to receive a driving force of the X-axis drive motor 170 x via intermediate members such as the first X-axis direction moving member 75 and the second X-axis direction moving member 76 while the Y-axis direction stage 71 is configured to receive a driving force of the Y-axis drive motor 170 y via an intermediate member such as the Y-axis direction moving member 80 in the above illustrated embodiments of the image stabilizers, it is possible for each of the X-axis direction stage and the Y-axis direction stage to be directly coupled to the associated drive source, with no such intermediate members therebetween.

Obvious changes may be made in the specific embodiments of the present invention d-shaped folded p such modifications being within the spirit and scope of the invention claimed. It is indicated that all matter contained herein is illustrative and does not limit the scope of the present invention. 

1. An image stabilizer for counteracting image shake of an object image formed on an image pickup device by moving said image pickup device, said image stabilizer comprising: an image-pickup-device holding member which holds said image pickup device; a guide device which guides said image-pickup-device holding member in a manner to allow said image-pickup-device holding member to move linearly in a plane orthogonal to an optical axis; a driving device which applies a moving force which moves said image-pickup-device holding member in a guide direction of said guide device to a force receiving portion on said image-pickup-device holding member; and a flexible printed wiring board which extends from said image pickup device, a part of said flexible printed wiring board being fixed to said image-pickup-device holding member at a fixing position thereon, wherein a distance between said fixing position and said force receiving portion is smaller than a distance between said guide device and said force receiving portion in a direction orthogonal to both said optical axis direction and said guide direction of said guide device.
 2. The image stabilizer according to claim 1, wherein said fixing position of said flexible printed wiring board is positioned between said force receiving portion and said guide device in said direction orthogonal to both said optical axis direction and said guide direction.
 3. The image stabilizer according to claim 1, wherein said image-pickup-device holding member comprises: a holding frame to which said image pickup device is fixed; and a flexible printed wiring board support member fixed to said holding frame behind said image pickup device, and wherein said flexible printed wiring board is fixed to a part of said flexible printed wiring board support member.
 4. The image stabilizer according to claim 1, further comprising: a biasing device which biases said image-pickup-device holding member in one of opposite directions of said guide direction of said guide device; and an intermediate member driven by said driving device to apply said moving force to said force receiving portion against a biasing force of said biasing device.
 5. The image stabilizer according to claim 4, wherein said intermediate member is directly in contact with said force receiving portion of said image-pickup-device holding member.
 6. The image stabilizer according to claim 4, wherein said intermediate member is coupled to said force receiving portion of said image-pickup-device holding member via a spring.
 7. The image stabilizer according to claim 4, wherein said intermediate member comprises: a first moving member which is movable along said guide direction of said guide device by a motor; and a second moving member which is guided along said guide direction and movable relative to said first moving member, wherein said second moving member applies said moving force to said force receiving portion on said image-pickup-device holding member.
 8. The image stabilizer according to claim 1, wherein said image stabilizer is incorporated in a digital camera.
 9. An image stabilizer of a digital camera, comprising: an image-pickup-device holding member which holds an image pickup device on which an object image is formed through a photographing optical system; a guide device which guides said image-pickup-device holding member in a manner to allow said image-pickup-device holding member to move linearly in at least one guide direction in a plane orthogonal to an optical axis of said photographing optical system; a driving device which applies a moving force to a force receiving portion on said image-pickup-device holding member to move said image-pickup-device holding member in said guide direction of said guide device; and a flexible printed wiring board which extends from said image pickup device in an internal space of a camera body, a part of said flexible printed wiring board being fixed to said image-pickup-device holding member at a fixing position thereon, wherein a distance between said fixing position and said force receiving portion is smaller than a distance between said guide device and said force receiving portion in a direction orthogonal to both said optical axis direction and said guide direction of said guide device. 